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Complex Variables Demystified
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Complex Variables Demystified David McMahon
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ABOUT THE AUTHOR
David McMahon has worked for several years as a physicist and researcher at Sandia National Laboratories. He is the author of Linear Algebra Demystified, Quantum Mechanics Demystified, Relativity Demystified, MATLAB® Demystified, and Quantum Field Theory Demystified, among other successful titles.
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CONTENTS
CHAPTER 1
CHAPTER 2
Preface
xi
Complex Numbers The Algebra of Complex Numbers Complex Variables Rules for the Complex Conjugate Pascal’s Triangle Axioms Satisfied by the Complex Number System Properties of the Modulus The Polar Representation The nth Roots of Unity Summary Quiz
1 2 4 5 9 10 12 12 16 19 19
Functions, Limits, and Continuity Complex Functions Plotting Complex Functions Multivalued Functions Limits of Complex Functions Limits Involving Infinity Continuity Summary Quiz
21 21 28 33 33 38 38 40 40
viii CHAPTER 3
Complex Variables Demystified The Derivative and Analytic Functions The Derivative Defined Leibniz Notation Rules for Differentiation Derivatives of Some Elementary Functions The Product and Quotient Rules The Cauchy-Riemann Equations The Polar Representation Some Consequences of the Cauchy-Riemann Equations Harmonic Functions The Reflection Principle Summary Quiz
41 42 43 45 47 48 51 57
CHAPTER 4
Elementary Functions Complex Polynomials The Complex Exponential Trigonometric Functions The Hyperbolic Functions Complex Exponents Derivatives of Some Elementary Functions Branches Summary Quiz
65 65 70 75 78 84 85 88 89 89
CHAPTER 5
Sequences and Series Sequences Infinite Series Convergence Convergence Tests Uniformly Converging Series Power Series Taylor and Maclaurin Series Theorems on Power Series Some Common Series
59 61 63 64 64
91 91 94 94 96 97 97 98 98 100
ix
Contents Laurent Series Types of Singularities Entire Functions Meromorphic Functions Summary Quiz
109 111 112 112 114 114
CHAPTER 6
Complex Integration Complex Functions w(t) Properties of Complex Integrals Contours in the Complex Plane Complex Line Integrals The Cauchy-Goursat Theorem Summary Quiz
117 117 119 121 124 127 133 134
CHAPTER 7
Residue Theory Theorems Related to Cauchy’s Integral Formula The Cauchy’s Integral Formula as a Sampling Function Some Properties of Analytic Functions The Residue Theorem Evaluation of Real, Definite Integrals Integral of a Rational Function Summary Quiz
135 135 143 144 148 151 155 161 161
CHAPTER 8
More Complex Integration and the Laplace Transform Contour Integration Continued The Laplace Transform The Bromvich Inversion Integral Summary Quiz
163 163 167 179 181 181
Mapping and Transformations Linear Transformations The Transformation zn Conformal Mapping
183 184 188 190
CHAPTER 9
x
Complex Variables Demystified The Mapping 1/z Mapping of Infinite Strips Rules of Thumb Möbius Transformations Fixed Points Summary Quiz
190 192 194 195 201 202 202
CHAPTER 10
The Schwarz-Christoffel Transformation The Riemann Mapping Theorem The Schwarz-Christoffel Transformation Summary Quiz
203 203 204 207 207
CHAPTER 11
The Gamma and Zeta Functions The Gamma Function More Properties of the Gamma Function Contour Integral Representation and Stirling’s Formula The Beta Function The Riemann Zeta Function Summary Quiz
209 209 219
Boundary Value Problems Laplace’s Equation and Harmonic Functions Solving Boundary Value Problems Using Conformal Mapping Green’s Functions Summary Quiz
231 231
Final Exam Quiz Solutions Final Exam Solutions Bibliography Index
249 255 261 267 269
CHAPTER 12
224 224 225 230 230
234 244 247 247
PREFACE
Complex variables, and its more advanced version, complex analysis, is one of the most fascinating areas in pure and applied mathematics. It all started when mathematicians were mystified by equations that could only be solved if you could take the square roots of negative numbers. This seemed bizarre, and back then nobody could imagine that something as strange as this could have any application in the real world. Thus the term imaginary number was born and the area seemed so odd it became known as complex. These terms have stuck around even though the theory of complex variables has found a home as a fundamental part of mathematics and has a wide range of physical applications. In mathematics, it turns out that complex variables are actually an extension of the real variables. A student planning on becoming a professional pure or applied mathematician should definitely have a thorough grasp of complex analysis. Perhaps the most surprising thing about complex variables is the wide range of applications it touches in physics and engineering. In many of these applications, complex variables proves to be a useful tool. For example, because of Euler’s identity, a formula we use over and over again in this book, electromagnetic fields are easier to deal with using complex variables. Other areas where complex variables plays a role include fluid dynamics, the study of temperature, electrostatics, and in the evaluation of many real integrals of functions of a real variable. In quantum theory, we meet the most surprising revelation about complex variables. It turns out they are not so imaginary at all. Instead, they appear to be as “real” as real numbers and even play a fundamental role in the working of physical systems at the microscopic level. In the limited space of this book, we won’t be able to cover the physical applications of complex variables. Our purpose here is to build a solid foundation to get you started on the subject. This book is filled with a large number of solved
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xii
Complex Variables Demystified
examples (many of which are at the advanced undergraduate level) that will show you how to tackle problems in complex variables, with explicit detail. Topics covered include: • Complex numbers, variables, and the polar representation • Limits and continuity • Derivatives and the Cauchy-Riemann equations • Elementary functions like the exponential and trigonometric functions • Complex integration • The residue theorem • Conformal mapping • Sequences, infinite series, and Laurent series • The gamma and zeta functions • Solving boundary value problems This book should provide the reader with a good introduction to the subject of complex variables. After completing this book, you will be able to deepen your knowledge of the subject by consulting one of the excellent texts listed in the references at the end of the book. I would like to thank Steven G. Krantz for his very thoughtful and thorough review of this manuscript. David McMahon
CHAPTER 1
Complex Numbers
In the early days of modern mathematics, people were puzzled by equations like this one: x2 + 1 = 0 The equation looks simple enough, but in the sixteenth century people had no idea how to solve it. This is because to the common-sense mind the solution seems to be without meaning: x = ± −1 For this reason, mathematicians dubbed −1 an imaginary number. We abbreviate this by writing “i” in its place, that is: i = −1
Copyright © 2008 by The McGraw-Hill Companies, Inc. Click here for terms of use.
(1.1)
2
Complex Variables Demystified
So we see that i 2 = −1, and we can solve equations like x 2 + 1 = 0. Note that electrical engineers use j = −1, but we will stick with the standard notation used in mathematics and physics.
The Algebra of Complex Numbers More general complex numbers can be written down. In fact, using real numbers a and b we can form a complex number: c = a + ib
(1.2)
We call a the real part of the complex number c and refer to b as the imaginary part of c. The numbers a and b are ordinary real numbers. Now let c = a + ib and k = m + in be two complex numbers. Here m and n are also two arbitrary real numbers (not integers, we use m and n because I am running out of symbols to use). We can form the sum and difference of two complex numbers by adding (subtracting) their real and imaginary parts independently. That is: c + k = a + ib + m + in = ( a + m ) + i ( b + n ) c − k = a + ib − ( m + in ) = (aa − m ) + i ( b − n ) To multiply two complex numbers, we just multiply out the real and imaginary parts term by term and use i 2 = −1, then group real and imaginary parts at the end: ck = ( a + ib )( m + in ) = am + ian + ibm + i 2 bn = am + ian + ibm − bn = ( am − bn ) + i ( an + bm ) To divide two complex numbers and write the result in the form c = a + ib, we’re going to need a new concept, called the complex conjugate. We form the complex conjugate of any complex number by letting i → − i . The complex conjugate is indicated by putting a bar on top of the number or variable. Again, let c = a + ib . Then the complex conjugate is c = a − ib
(1.3)
It’s easy to see that if c is purely real, that is, c = a, then the complex conjugate is c = a = a . On the other hand, if c is purely imaginary, then c = ib. This means that c = ib = − ib = − c. Taking the complex conjugate twice gives back the original number: c = a − ib = a + ib = c
CHAPTER 1
Complex Numbers
3
Notice what happens when we multiply a complex number by its conjugate: cc = ( a + ib )( a − ib ) = a 2 − iab + iba − i 2 b 2 = a2 − i 2b2 = a2 + b2 We call the quantity cc the modulus of the complex number c and write 2
c = cc
(1.4)
Note that in physics, the complex conjugate is often denoted by an asterisk, that is, c*. The modulus of a complex number has geometrical significance. This is because we can view a complex number as a vector in the plane with components given by the real and imaginary parts. The length of the vector corresponds to the modulus. We will discuss this concept again later (see Fig. 1.1). Now we can find the result of c/k , provided that k ≠ 0 of course. We have c a + ib = k m + in a + ib ( m − in ) = m + in ( m − in ) am + ibm − ian + bn = m2 + n2 am + bn bm − an +i 2 = 2 2 m +n m + n2
y
Im
z = x + iy r θ
Re x z = x – iy
Figure 1.1 The complex plane, showing z = x + iy and its complex conjugate as vectors.
Complex Variables Demystified
4
We say that two complex numbers are equal if and only if their real and imaginary parts are equal. That is, c = a + ib and k = m + in are equal if and only if a=m ⇒c=k
b=n
Complex Variables In the early days, all of this probably seemed like a neat little trick that could be used to solve obscure equations, and not much more than that. But in reality it opened up a Pandora’s box of possibilities that is still being dealt with today. It turns out that an entire branch of analysis called complex analysis can be constructed, which really supersedes real analysis. Complex analysis has not only transformed the world of mathematics, but surprisingly, we find its application in many areas of physics and engineering. For example, we can use complex numbers to describe the behavior of the electromagnetic field. In atomic systems, which are described by quantum mechanics, complex numbers and complex functions play a central role, and actually appear to be a fundamental part of nature. Complex numbers are often hidden. For example, as we’ll see later, the trigonometric functions can be written down in surprising ways like: cos θ =
eiθ + e − iθ 2
sin θ =
eiθ + e − iθ 2i
It appears that complex numbers are not so “imaginary” after all; rather they are used in a wide variety of engineering and science applications. The first step in moving forward toward a calculus based on complex numbers is to abstract the notion of a complex number to a complex variable. This is the same as abstracting the notion of a real number to a variable like x that we can use to solve algebraic equations. We use z to represent a complex variable. Its real and imaginary parts are represented by the real variables x and y, respectively. So we write z = x + iy
(1.5)
The complex conjugate is then z = x − iy A complex number and its conjugate have an interesting origin in the study of polynomials with real coefficients. Let p be a polynomial with real coefficients and suppose that a complex number z is a root of p. Then it follows that the complex conjugate z is a root of p also.
CHAPTER 1
Complex Numbers
5
The modulus of the complex variable z is given by 2
z = x 2 + y2
⇒ z = x 2 + y2
(1.6)
The same rules for addition, subtraction, multiplication, and division we illustrated with complex numbers apply to complex variables. So if z = x + iy and w = u + iv then zw = ( x + iy )(u + iv) = ( xu − yv ) + i ( yu + xv ) We can graph complex numbers in the x-y plane, which we sometimes call the complex plane or the z plane. The y axis is the imaginary axis and the x axis is the real axis. A complex number z = x + iy can be depicted as a vector in the complex plane, with a length r given by its modulus: r = z = x 2 + y2
(1.7)
We also keep track of the angle θ that this vector makes with the real axis. The complex conjugate is a vector reflected across the real axis. This is easy to understand since we form the conjugate by letting y → − y. These ideas are illustrated in Fig. 1.1.
Rules for the Complex Conjugate Let z = x + iy and w = u + iv be two complex variables. Then z+w= z +w zw = z w
(1.8)
⎛ z⎞ z ⎜⎝ ⎟⎠ = w w These properties are easy to demonstrate. For example, we prove the first one: z + w = ( x + iy ) + (u + iv ) = ( x + u) + i( y + v) = ( x + u) − i( y + v) = x − iy + u − iv = z +w
Complex Variables Demystified
6
If z ≠ 0, we can form the multiplicative inverse of z which we denote by z−1. The inverse has the property that zz −1 = 1
(1.9)
It is given by z
z −1 =
z
2
=
1 z
(1.10)
We can verify that this works explicitly in two ways:
zz −1 = z
z z
2
=
zz −1 = ( x + iy)
z
2
z
2
=1
x − iy x 2 + y2 = =1 x 2 + y2 x 2 + y2
Notice that the inverse gives us a way to write the quotient of two complex numbers, allowing us to do division: z zw zw = = 2 w ww w EXAMPLE 1.1 Find the complex conjugate, sum, product, and quotient of the complex numbers z = 2 − 3i
w = 1+ i
SOLUTION To find the complex conjugate of each complex number we let i → − i . Hence z = 2 − 3i = 2 + i 3 w = 1+ i = 1− i
CHAPTER 1
Complex Numbers
7
The sum of the two complex numbers is formed by adding the real and imaginary parts, respectively: z + w = ( 2 − 3i ) + (1 + i ) = ( 2 + 1) + i ( −3 + 1) = 3 − 2i We can form the product as follows: zw = ( 2 − 3i )(1 + i ) = 2 − 3i + 2i − 3i 2 = ( 2 + 3) + i ( −3 + 2 ) = 5−i Finally, we use the complex conjugate of w to form the quotient: z z ⎛ w ⎞ ( 2 − 3i ) (1 − i ) 2 − 3i − 2i + 3i 2 2 − 3 − 5i −1 − 5i = ⎜ ⎟= = = = w w ⎝ w ⎠ (1 + i ) (1 − i ) 1 + i − i − i2 1+1 2 EXAMPLE 1.2 Earlier, we said that if z = x + iy, then x is the real part of z [denoted by writing x = Re( z ) say] and that y is the imaginary part of z [ y = Im( z )]. Derive expressions that allow us to define the real and imaginary parts of a complex number using only z and its complex conjugate. SOLUTION First let’s write down the complex variable and its complex conjugate: z = x + iy
z = x − iy
Now we see that this is just simple algebra. We can eliminate y from both equations by adding them: z + z = x + iy + x − iy = 2 x So, we find that the real part of z is given by Re( z ) = x =
z+z 2
(1.11)
Complex Variables Demystified
8
Now, let’s subtract the complex conjugate from z instead, which allows us to eliminate x: z − z = x + iy − ( x − iy) = x + iy − x + iy = 2iy z−z ⇒ Im( z ) = y = (1.12) 2i EXAMPLE 1.3 2 Find z if z = (2 + i ) /[4i − (1 + 2i )]. SOLUTION Note that when the modulus sign is not present, we square without computing the 2 2 complex conjugate. That is z = zz but z = z ⋅ z, which is a different quantity. So in this case we have ⎛ 2+i ⎞ z2 = ⎜ ⎝ 4i − (1 + 2i ) ⎟⎠
2
⎛ 2+i ⎞ ⎛ 2+i ⎞ =⎜ ⎜ ⎟ ⎝ 4i − (1 + 2i ) ⎠ ⎝ 4i − (1 + 2i ) ⎟⎠ ⎛ ⎞ 4 + 4i + i 2 =⎜ ⎟ ⎝ (−1 + 2i )(−1 + 2i ) ⎠ ⎛ 3 + 4i ⎞ =⎜ ⎝ −3 − 4i ⎟⎠ ⎡ (3 + 4i )(−3 + 4i ) ⎤ =⎢ ⎥ (multiply and divide by complex conjugate of denominator) ⎣ (−3 − 4i )(−3 + 4i) ⎦ −9 − 12i + 12i − 16 −25 = = −1 = 25 9 + 12i − 12i + 16 EXAMPLE 1.4 Show that 1/i = − i. SOLUTION This is easy, using the rule we’ve been applying for division. That is: z z ⎛ w⎞ = ⎜ ⎟ w w ⎝ w⎠
CHAPTER 1
Complex Numbers
9
Hence −i 1 1 ⎛ −i ⎞ −i = −i = = ⎜ ⎟= 2 ⎝ ⎠ i i −i − (i ) − ( −1) EXAMPLE 1.5 Find z if z( 7 z + 14 − 5i ) = 0 . SOLUTION One obvious solution to the equation is z = 0. The other one is found to be 7 z + 14 − 5i = 0 ⇒ 7 z = −14 + 5i or 5 z = −2 + i 7
Pascal’s Triangle Expansions of complex numbers can be written down immediately using Pascal’s triangle, which lists the coefficients in an expansion of the form ( x + y )n . We list the first five rows here: 1 1 1 1 2 1 1 3 3 1 1 4 6 4 1
(1.13)
The first row corresponds to ( x + y )0, the second row to ( x + y )1, and so on. For example, looking at the third row we have coefficients 1, 2, 1. This means that ( x + y )2 = x 2 + 2 xy + y 2 EXAMPLE 1.6 Write ( 2 − i )4 in the standard form a + ib.
Complex Variables Demystified
10
SOLUTION The coefficients for the fourth power are found in row five of Pascal’s triangle. In general: ( x + y )4 = x 4 + 4 x 3 y + 6 x 2 y 2 + 4 xy3 + y 4 Hence ( 2 − i )4 = 2 4 + 4( 2 3 )( −i ) + 6( 2 2 )( −i )2 + 4( 2 )( −i )3 + ( −i )4 = 16 − 32i + 24( − i )2 + 8( − i )3 + ( − i )4
Now let’s look at some of the terms involving powers of –i individually. First we have ( − i )2 = ( −1)2 i 2 = ( +1)( −1) = −1 The last two terms are ( − i )3 = ( −1)3 i 3 = ( −1)(i ⋅ i 2 ) = ( −1)(i )( −1) = +i ( − i )4 = [( −i )2 ]2 = ( −1)2 = +1 Therefore we have ( 2 − i )4 = 16 − 32i + 24( − i )2 + 8( − i )3 + ( − i )4 = 16 − 32i − 24 + 8i + 1 = −7 − 24i
Axioms Satisfied by the Complex Number System We have already seen some of the basics of how to handle complex numbers, like how to add or multiply them. Now we state the formal axioms of the complex number system which allow mathematicians to describe complex numbers as a
CHAPTER 1
Complex Numbers
11
field. These axioms should be familiar since their general statement is similar to that used for the reals. We suppose that u, w, z are three complex numbers, that is, u, w, z ∈. Then these axioms follow: z+w
and
zw ∈ (closure law)
z+w= w+z
(commutative law of addition)
u + ( w + z ) = (u + w) + z (associative law of additio) zw = wz u( wz ) = (uw) z u( w + z ) = uw + uz
(1.14) (1.15) (1.16)
(ccommutative law of multiplication)
(1.17)
(associative law of multiplication)
(1.18)
(distributive law)
(1.19)
The identity with respect to addition is given by z = 0 + 0i , which satisfies z+0= 0+z
(1.20)
The identity with respect to multiplication is given by z = 1 + i 0 = 1, which satisfies z ⋅1 = 1 ⋅ z = z
(1.21)
For any complex number z there exists an additive inverse, which we denote by –z that satisfies z + (− z) = (− z) + z = 0
(1.22)
−1 There also exists a multiplicative inverse z , which we have seen satisfies
zz −1 = z −1z = 1
(1.23)
A set that satisfies properties in Eqs. (1.14)–(1.23) is called a field. The algebraic closure property in Eq. (1.14) illustrates that you can add two complex numbers together and you get another complex number (that is what we mean by closed). The complex numbers are the smallest algebraically closed field that contains the reals as a subset.
12
Complex Variables Demystified
Properties of the Modulus We have already seen that the modulus or magnitude or absolute value of a complex number is defined by multiplying it by its complex conjugate and taking the positive square root. The absolute value operator satisfies several properties. Let z1 , z2 , z3 ,… , zn be complex numbers. Then z1z2 = z1 z2 z1z2 z3 … zn = z1 z2 z3 … zn z z1 = 1 z2 z2
(1.24) (1.25)
(1.26)
A relationship called the triangle inequality deserves special attention: z1 + z2 ≤ z1 + z2
(1.27)
z1 + z2 + + zn ≤ z1 + z2 + + zn
(1.28)
z1 + z2 ≥ z1 − z2
(1.29)
z1 − z2 ≥ z1 − z2
(1.30)
Also note that wz + zw = 2 Re( zw ) ≤ 2 z w .
The Polar Representation In Fig. 1.1, we showed how a complex number can be represented by a vector in the x-y plane. Using polar coordinates, we can develop an equivalent polar representation of a complex number. We say that z = x + iy is the Cartesian representation of a complex number. To write down the polar representation, we begin with the definition of the polar coordinates (r ,θ ): x = r cos θ
y = r sin θ
(1.31)
CHAPTER 1
Complex Numbers
13
We have already seen that when we represent a complex number as a vector in the plane the length of that vector is r. Hence, carrying forward with the vector analogy, the modulus of z is given by r = x 2 + y 2 = x + iy
(1.32)
Using Eq. (1.31), we can write z = x + iy as z = x + iy = r cosθ + ir sin θ = r (cosθ + i sin θ )
(1.33)
Note that r > 0 and that we have tan θ = y / x as a means to convert between polar and Cartesian representations.
THE ARGUMENT OF Z The value of θ for a given complex number is called the argument of z or arg z. The principal value of arg z which is denoted by Arg z is the value −π < Θ ≤ π . The following relationship holds: arg z = Arg z + 2 nπ
n = 0, ±1, ±2,...
(1.34)
The principal value can be specified to be between 0 and 2π .
EULER’S FORMULA Euler’s formula allows us to write the expression cos θ + i sin θ in terms of a complex exponential. This is easy to see using a Taylor series expansion. First let’s write out a few terms in the well-known Taylor expansions of the trigonometric functions cos and sin: 1 1 1 cos θ = 1 − θ 2 + θ 4 − θ 6 + 2 4! 6! sin θ = θ −
1 3 1 5 θ + θ − 3! 5!
(1.35)
(1.36)
Complex Variables Demystified
14
Now, let’s look at eiθ . The power series expansion of this function is given by 1 1 1 1 eiθ = 1 + iθ + (iθ )2 + (iθ )3 + (iθ )4 + (iθ )5 + 2 3! 4! 5! 1 1 1 1 = 1 + iθ − θ 2 − i θ 3 + θ 4 + i θ 5 + 2 3! 4! 5! (Now group terms—looking for sin and cosine) ⎛ 1 ⎞ ⎛ ⎞ 1 1 1 = ⎜ 1 − θ 2 + θ 4 − ⎟ + ⎜ iθ − i θ 3 + i θ 5 + ⎟ 4! 3! 5! ⎠ ⎝ 2 ⎠ ⎝ ⎛ 1 ⎞ ⎞ ⎛ 1 1 1 = ⎜ 1 − θ 2 + θ 4 − ⎟ + i ⎜ θ − θ 3 + θ 5 + ⎟ 4! 3! 5! ⎝ 2 ⎠ ⎝ ⎠ = cos θ + i sin θ So, we conclude that eiθ = cos θ + i sin θ
(1.37)
e − iθ = cos θ − i sin θ
(1.38)
As noted in the introduction, these formulas can be inverted using algebra to obtain the following relationships: cos θ =
eiθ + e − iθ 2
(1.39)
sin θ =
eiθ − e − iθ 2i
(1.40)
These relationships allow us to write a complex number in complex exponential form or more commonly polar form. This is given by z = reiθ
(1.41)
The polar form can be very useful for calculation, since exponentials are so simple to work with. For example, the product of two complex numbers z = reiθ and w = ρeiφ is given by zw = (reiθ )( ρeiφ ) = r ρei(θ +φ )
(1.42)
CHAPTER 1
Complex Numbers
15
Notice that moduli multiply and arguments add. Division is also very simple: z reiθ r iθ iφ r i(θ −φ ) = = e e = e w ρeiφ ρ ρ
(1.43)
The reciprocal of a complex number takes on the relatively simple form: 1 z = reiθ ⇒ z −1 = e − iθ r
(1.44)
Raising a complex number to a power is also easy: z n = (reiθ )n = r n einθ
(1.45)
The complex conjugate is just z = re − iθ
(1.46)
Euler’s formula can be used to derive some interesting expressions. For example, we can easily derive one of the most mysterious equations in all of mathematics: eiπ = cos π + i sin π ⇒ eiπ + 1 = 0
(1.47)
DE MOIVRE’S THEOREM Let z1 = r1 (cos θ1 + i sin θ1 ) and z2 = r2 (cos θ 2 + i sin θ 2 ). Using trigonometric identities and some algebra we can show that z1z2 = r1r2 [cos(θ1 + θ 2 ) + i sin(θ1 + θ 2 )] z1 / z2 =
r1 [cos(θ1 − θ 2 ) + i sin(θ1 − θ 2 )] r2
z1z2 … zn = r1r2 … rn [cos(θ1 + θ 2 + + θ n ) + i sin(θ1 + θ 2 + + θ n )]
(1.48) (1.49) (1.50)
Complex Variables Demystified
16 De Moivre’s formula follows:
z n = [r (cos θ + i sin θ )]n = r n (cos nθ + i sin nθ )
(1.51)
The nth Roots of Unity Consider the equation zn = 1 where n is a positive integer. This innocuous looking equation actually has a bit of hidden data in it, this comes from the fact that ( e z )n = e z e z e z The nth roots of unity are given by cos 2 kπ / n + i sin 2 kπ / n = e 2 kπ i / n
k = 0,1, 2,… , n − 1
If w = e 2π i / n then the n roots are 1, w, w 2 ,… , w n−1. EXAMPLE 1.7 Show that cos z = cos x cosh y − i sin x sinh y. SOLUTION This can be done using Euler’s formula: ei ( x +iy ) + e − i ( x +iy ) 2 eix− y + e − ix + y = 2 ix − y e + e − ix + y + eix− y + e − ix + y = 4
cos( x + iy) =
(1.52)
CHAPTER 1
Complex Numbers
Now we can add and subtract some desired terms: eix− y + e − ix + y + eix− y + e − ix + y 4 eix + y + e − ix + y + eix − y + e − ix− y − eix + y + e − ix + y + e − ix + y − e − ix − y = 4 ix + y − ix + y ix − y − ix − y +e +e eix + y − e − ix + y − e − ix + y + e − ix− y e +e − = 4 4 − ix y ix − ix y −y ix ⎛ e + e ⎞ ⎛ e + e ⎞ ⎛ e − e ⎞ ⎛ e − e− y ⎞ =⎜ ⎟⎠ ⎜⎝ 2 ⎟⎠ − ⎜⎝ 2 2 ⎟⎠ ⎜⎝ 2 ⎟⎠ ⎝ ⎛ eix + e − ix ⎞ ⎛ e y + e − y ⎞ ⎛ eix − e − ix ⎞ ⎛ e y − e − y ⎞ =⎜ ⎟⎠ ⎜⎝ 2 ⎟⎠ − i ⎜⎝ 2i ⎟⎠ ⎜⎝ 2 ⎟⎠ 2 ⎝ = cos x cosh y − i sin x sinh y
EXAMPLE 1.8 Show that sin −1 z = − i ln(iz ± 1 − z 2 ).
SOLUTION We start with the relation cos 2 θ + sin 2 θ = 1 This means that we can write cos θ = ± 1 − sin 2 θ Now let θ = sin −1 z. Then we have cos(sin −1 z ) = ± 1 − sin 2 (sin −1 z ) = ± 1 − z 2 This is true because sin(sin −1 (φ )) = φ. Now we turn to Euler’s formula: eiθ = cos θ + i sin θ
17
Complex Variables Demystified
18 Again, setting θ = sin −1 z we have ei sin
−1
z
= cos(sin −1 z ) + i sin(sin −1 z )
= ± 1 − z 2 + iz Taking the natural logarithm of both sides, we obtain the desired result: i sin −1 z = ln(iz ± 1 − z 2 ) ⇒ sin −1 z = − i ln(iz ± 1 − z 2 ) EXAMPLE 1.9 Show that e ln z = reiθ. SOLUTION We use the fact that θ = θ + 2nπ for n = 0,1, 2,... to get e ln z = e ln( re
iθ
)
= e ln r +ln( e
iθ
)
= e ln r +iθ = e ln r +i (θ +2 nπ ) = reiθ ei 2 nπ = reiθ (cos 2 nπ + i sin 2 nπ ) = reiθ EXAMPLE 1.10 Find the fourth roots of 2. SOLUTION We find the nth roots of a number a by writing r n einθ = a ei 0 and equating moduli and arguments, and repeating the process by adding 2π . This may not be clear, but we’ll show this with the current example. First we start out with (reiθ )4 = 2ei 0 ⇒ r = 21/ 4
θ=0
This is the first of four roots. The second root is (reiθ )4 = r 4 ei 4θ = 2ei 2π ⇒ r = 21/ 4
θ=
π 2
CHAPTER 1
Complex Numbers
19
So the second root is z = 21/ 4 eiπ / 2 = 21/ 4 [cos(π / 2) + i sin(π / 2)] = i 21/ 4 . Next, we have (reiθ )4 = r 4 ei 4θ = 2ei 4 π ⇒ r = 21/ 4
θ =π
And the root is z = 21/ 4 eiπ = 21/ 4 (cos π + i sin π ) = −21/ 4 The fourth and final root is found using (reiθ )4 = r 4 ei 4θ = 2ei 6π 3π θ= ⇒ r = 21/ 4 2 In Cartesian form, the root is ⎛ ⎛ 3π ⎞ ⎛ 3π ⎞ ⎞ z = 21/ 4 eiπ = 21/ 4 ⎜ cos ⎜ ⎟ + i sin ⎜ ⎟ ⎟ = −i21/ 4 ⎝ 2⎠ ⎝ 2 ⎠⎠ ⎝
Summary The imaginary unit i = −1 can be used to solve equations like x 2 + 1 = 0. By denoting real and imaginary parts, we can construct complex numbers that we can add, subtract, multiply, and divide. Like the reals, the complex numbers form a field. These notions can be abstracted to complex variables, which can be written in Cartesian or polar form.
Quiz 1. What is the modulus of z = 2. Write z =
1− i ? 4
2 − 4i in standard form z = x + iy. 3 + 2i − i 5
20
Complex Variables Demystified
3. Find the sum and product of z = 2 + 3i , w = 3 − i . 4. Write down the complex conjugates of z = 2 + 3i , w = 3 − i . i . 5. Find the principal argument of −2 − 2i 6. Using De Moivre’s formula, what is sin 3θ ? 7. Following the procedure outlined in Example 1.7, find an expression for sin( x + iy ). 8. Express cos −1 z in terms of the natural logarithm. 9. Find all of the cube roots of i. 10. If z = 16eiπ and w = 2eiπ / 2, what is
z ? w
CHAPTER 2
Functions, Limits, and Continuity
In the last chapter, although we saw a couple of functions with complex argument z, we spent most of our time talking about complex numbers. Now we will introduce complex functions and begin to introduce concepts from the study of calculus like limits and continuity. Many important points in the first few chapters will be covered several times, so don’t worry if you don’t understand everything right away.
Complex Functions When we write z, we are denoting a complex variable, which is a symbol that can take on any value of a complex number. This is the same concept you are used to from real variables where we use x or y to represent a variable. We define a function of a complex variable w = f ( z ) as a rule that assigns to each z ∈ a complex
Copyright © 2008 by The McGraw-Hill Companies, Inc. Click here for terms of use.
Complex Variables Demystified
22
number w. If the function is defined only over a restricted set S, then w = f ( z ) assigns to each z ∈ S the complex number w and we call S the domain of the function. The value of a function at z = a is indicated by writing f (a). EXAMPLE 2.1 3 Consider the function f ( z ) = z and consider its value at z = i , z = 1 + i. SOLUTION In the first case we set z = i and so we have f (i ) = i 3 = i (i 2 ) = − i Now we let z = 1 + i. Since z 2 = (1 + i )2 = (1 + i )(1 + i ) = 1 + 2i − 1 = 2i The value of the function is f (1 + i ) = (1 + i )3 = (1 + i )2 (1 + i ) = 2i (1 + i ) = −2 + 2i A complex function can be a function of the complex conjugate z as well, so we could write f ( z , z ). That is, we are treating z and its conjugate z as independent variables the way we might for a function of x and y, g( x , y). Just as we could compute partial derivatives ∂g/∂x and ∂g/∂y to determine how g depends on x and y, we can determine how a complex function depends on z and its conjugate z by computing partial derivatives of the function with respect to each of these variables. As we will see in the next chapter, functions that do not depend on z have important properties, and in fact the study of complex analysis is the study of functions for which ∂f /∂z = 0. EXAMPLE 2.2 2 Suppose that f ( z ) = z z . Find f (1 + i ) SOLUTION 2 2 In Example 2.1, we saw that z = (1 + i ) = 2i. The complex conjugate of z = 1 + i is given by z = 1− i
CHAPTER 2
Functions, Limits, and Continuity
23
So we have f (1 + i ) = z 2 z = (1 + i )2 (1 − i ) = 2i (1 − i ) = 2 + 2i The domain of a function can be restricted to a region where the function is well behaved. For example, the function f (z) =
1 z
is not defined at the origin. Let S be a domain that includes a region where the function is defined. Suppose that D is a region where the function is not defined. We can indicate that we are excluding a certain set from the domain of the function using the notation z ∈S \ D
(2.1)
For example, letting f ( z ) = 1/ z , we see that the function is defined throughout the complex plane except at the origin. We can indicate this by writing z ∈ \ {0}
(2.2)
Simply put, the domain of a function is a region where the function does not blow up. EXAMPLE 2.3 What is the domain of definition for f ( z ) = 1/(1 + z 2 ). SOLUTION We can factorize the denominator and write the function in the following way: f (z) =
1 1 = 2 1+ z (i + z )(− i + z )
We can see that the function goes to infinity if z = ±i Therefore the function is defined throughout the complex plane except at the points z = ± i . Something we’ll repeatedly emphasize in the next couple of chapters is that a function, just like a complex number, can be written in terms of real and imaginary parts. Recall that the complex variable z can be written as z = x + iy. We call x the
24
Complex Variables Demystified
real part of z and y the imaginary part of z, but both x and y are themselves real variables. This concept carries over to a complex function, which can be written in the form f ( z ) = f ( x + iy) = u( x , y) + iv ( x , y) . The real part of f is given by Re( f ) = u( x , y)
(2.3)
And the imaginary part of f is given by Im( f ) = v ( x , y)
(2.4)
Notice that we can write down the complex conjugate of a function. With f ( z ) = f ( x + iy) = u( x , y) + iv ( x , y) the complex conjugate is given by f ( z ) = f ( x + iy) = u( x , y) − iv ( x , y)
(2.5)
The same rule applied to complex numbers and complex variables was used, namely, we let i → − i in order to obtain the complex conjugate. Note that u( x , y) and v ( x , y) are unchanged by this operation because they are both real functions of the real variables x and y. In chap. 1, we learned how to write the real and imaginary parts of z in terms of z , z using Eqs. (1.11) and (1.12). We can write down analogous formulas for the real and imaginary parts of a function. First let’s consider the real part of a complex function. We can add the function to its complex conjugate f + f = u + iv + u − iv = 2u Hence the real part of a complex function is given by u ( x , y) =
f (z) + f (z) 2
(2.6)
And we can take the difference between a function and its complex conjugate: f − f = u + iv − (u − iv ) = 2iv This gives us the imaginary part of a complex function: v ( x , y) =
f (z) − f (z) 2i
EXAMPLE 2.4 What is the complex conjugate of f(z) = 1/z.
(2.7)
CHAPTER 2
Functions, Limits, and Continuity
25
SOLUTION First of all we can write the function as f ( z ) = f ( x + iy) =
1 x + iy
Therefore the complex conjugate is ⎛ 1 ⎞ 1 1 f =⎜ = = ⎟ ⎝ x + iy ⎠ x − iy z EXAMPLE 2.5 What are the real and imaginary parts of f ( z ) = z + (1/z ). SOLUTION We let z = x + iy. Then we have f ( x + iy) = x + iy +
1 x + iy
We need to write the second term in standard Cartesian notation. This is done by multiplying and dividing by its complex conjugate: 1 1 ⎛ x − iy ⎞ x − iy = = 2 ⎜ ⎟ x + iy x + iy ⎝ x − iy ⎠ x + y 2 So, we have f ( x + iy ) = x + iy + =x+ =
x − iy x 2 + y2
iy x + iy − 2 x + y2 x 2 + y2
x 3 + xy 2 + x ⎛ y3 + x 2 y − y ⎞ + i⎜ ⎝ x 2 + y 2 ⎟⎠ x 2 + y2
So the real part of the function is Re( f ) =
x 3 + xy 2 + x = u ( x , y) x 2 + y2
Complex Variables Demystified
26
The imaginary part of the function is Im( f ) =
y3 + x 2 y − y = v ( x , y) x 2 + y2
Note that we can write the real and imaginary parts in terms of z , z as follows. We have f (z) = z +
1 1 =z+ z z
Now 1 1 z z f + f =z+ +z + =z+z + + zz zz z z z+z ⎛z+z⎞ =⎜ zz + ⎟ ⎝ zz ⎠ zz =
z 2 z + zz 2 + z + z zz
So Re( f ) =
f + f z 2 z + zz 2 + z + z = 2 2 zz
To get the imaginary part we calculate 1 ⎛ 1⎞ z z f − f = z + −⎜z + ⎟ = z + z − − zz zz z ⎝ z⎠ ⎛z+z⎞ ⎛z+z⎞ =⎜ zz − ⎜ ⎝ zz ⎟⎠ ⎝ zz ⎟⎠ =
z 2 z + zz 2 − z − z zz
Therefore Im( f ) =
f − f z 2 z + zz 2 − z − z = 2i 2izz
CHAPTER 2
Functions, Limits, and Continuity
27
In chap. 1 we also learned that a complex number z = x + iy can be written in the polar representation z = reiθ . The same is true with complex functions. That is, we can write f ( z ) = f (reiθ )
(2.8)
The function can also be written in terms of real and imaginary parts that are functions of the real variables r and θ . This is done as follows: f (reiθ ) = u(r ,θ ) + iv (r ,θ )
(2.9)
EXAMPLE 2.6 Write the function f (z) = z + (1/z) in the polar representation. What are the real and imaginary parts of the function? SOLUTION We write the function in the polar representation by letting z = reiθ . This gives f (z) = z +
1 z
1 reiθ 1 = reiθ + e − iθ r = reiθ +
Recalling Euler’s formula, we can write e ± iθ = cos θ ± i sin θ . So the function becomes 1 f = reiθ + e − iθ r 1 = r (cos θ + i sin θ ) + (cos θ − i sin θ ) r 1 1 ⎛ ⎛ = cos θ ⎜ r + ⎞⎟ + i sin θ ⎜ r − ⎞⎟ ⎝ ⎝ r⎠ r⎠ =
sin θ 2 cos θ 2 (r − 1) (r + 1) + i r r
This allows us to identify the real part of the function as u(r ,θ ) =
cos θ 2 (r + 1) r
Complex Variables Demystified
28
The imaginary part of the function is given by v (r ,θ ) =
sin θ 2 (r − 1) r
Note that both the real and imaginary parts of the function are real functions of the real variables (r ,θ ) .
Plotting Complex Functions One of the most useful tools in the study of real functions is the ability to graph or plot them. This lets us get a feel for the functions behavior, for example we can see how it behaves as x gets large or look for points of discontinuity. Unfortunately, in the case of a complex function we can’t just plot the function the way we would a real function f ( x ) of the real variable x. But, there are a few things we can look at. We can plot • The real part of f ( z ) • The imaginary part of f ( z ) • The modulus or absolute value f ( z ) In addition, if the function is written in polar representation, we can plot the argument of the function arg( f ( z )). We can also make a level set or contour plots of these items, or can plot them for a fixed point on the real or imaginary axis. EXAMPLE 2.7 Plot the real and imaginary parts of f(z) = z + (1/z). SOLUTION In Example 2.5 we found that Re( f ) =
x 3 + xy 2 + x = u ( x , y) x 2 + y2
Im( f ) =
y3 + x 2 y − y = v ( x , y) x 2 + y2
and
Note that there is a singularity at the origin. A plot of the real part of the function is shown in Fig. 2.1. The imaginary part of the function has a similar form, as shown in Fig. 2.2. At the origin, the imaginary part of the function also blows up.
CHAPTER 2
Functions, Limits, and Continuity
10 8 6 Re ( f ) 4 2 0 –10
29
1 5 0 y –5 –5
0 x
5 10 –10
3 2 2 2 Figure 2.1 A plot of Re( f ) = ( x + xy + x ) /(x + y ) = u( x , y). The spike at the origin is a
point where the function blows up.
10 8 6 Im ( f ) 4 2 0 –10
10 5 0y –5 x
–5
0 5 10
–10
3 2 2 2 Figure 2.2 A plot of Im( f ) = ( y + x y − y) /(x + y ) = v ( x , y).
Complex Variables Demystified
30
EXAMPLE 2.8 Plot the absolute value of the function f(z) = z + (1/z). SOLUTION Let’s write down the absolute value of the function. It is given by f (z) = f (z) f (z) So we have 1⎞ ⎛ 1⎞ ⎛ f (z) f (z) = ⎜ z + ⎟ ⎜ z + ⎟ ⎝ z⎠ ⎝ z⎠ = zz + =
z z 1 + + z z zz
z2z 2 z2 + z 2 1 + + zz zz zz
z2z 2 + z2 + z 2 + 1 = zz Now we write this in terms of x and y: 2
f (z) =
z2z 2 + z2 + z 2 + 1 zz
=
( x + iy)2 ( x − iy)2 + ( x + iy)2 + ( x − iy)2 + 1 x 2 + y2
=
( x 2 − y 2 + 2ixy)( x 2 − y 2 − 2ixy) + 2xx 2 − 2 y 2 + 1 x 2 + y2
=
x 4 + 2 x 2 y2 + y4 + 2 x 2 − 2 y2 + 1 x 2 + y2
Notice that this function will blow up at the origin, where x = y = 0. The absolute value is the square root: f (z) =
x 4 + 2 x 2 y2 + y4 + 2 x 2 − 2 y2 + 1 x 2 + y2
A plot of this function is shown in Fig. 2.3. EXAMPLE 2.9 Plot the real part of f ( z ) = z + (1/z ) along the line x + i 2 , for −10 ≤ x ≤ 10 .
CHAPTER 2
Functions, Limits, and Continuity
10 8 6 f (z) 4 2 0 –10
31
10 5 0 y –5 –5
0 x
5 10 -10
Figure 2.3 A plot of f ( z ) for f ( z ) = z + (1/z ) .
SOLUTION Plotting with the real or imaginary part fixed like this is another way to study the behavior of the function. The real part is given by Re( f ) =
x 3 + xy 2 + x = u ( x , y) x 2 + y2
Setting y = 2 gives u( x , 2) =
x 3 + 5x x2 + 4
A plot of this function is shown in Fig. 2.4. EXAMPLE 2.10 Generate a contour plot of f(z) = 1/z. SOLUTION A contour plot is a good way of visualizing where a function is increasing, decreasing, or blowing up. We show a contour plot of f ( z ) = 1/z in Fig. 2.5 generated with computer software. The plot shows increasing values in lighter
Complex Variables Demystified
32
Re ( f ) 10
5
–10
–5
5
10
x
–5
–10 3 2 2 2 Figure 2.4 A plot of Re( f ) = ( x + xy + x ) /(x + y ) = u( x , y) with y = 2.
4
2
0
–2
–4
–4
–2
0
2
4
Figure 2.5 A contour plot of f ( z ) = 1/z , showing zones where the function is increasing in magnitude and the point where it blows up at the origin.
CHAPTER 2
Functions, Limits, and Continuity
33
colors—note the area about and including the origin is white indicating that the function blows up there.
Multivalued Functions In many cases that we encounter in the theory of complex variables a function is multivalued. This is due to the periodic nature of the cosine and sin functions, Euler’s formula eiθ = cos θ + i sin θ and the fact that we can write z = reiθ in the polar representation. We say that a complex function f (z) is single valued if only one value of w corresponds to each value of z where w = f ( z ). If more than one value of w corresponds to each value of z, we say that the function is multivalued. A classic example of a multivalued function in complex variables is ln z, which we discuss in chap. 4.
Limits of Complex Functions Our first foray into the application of calculus to functions of a complex variable comes with the study of limits. Consider a point in the complex plane z = a and let f ( z ) be defined and single valued in some neighborhood about a. The neighborhood may include the point a, or we may omit a in which case we say that the function is defined and single valued in a deleted neighborhood of a. The limit of f ( z ) as z → a is written as lim f ( z ) = z →a
(2.10)
Formally, what this means is that for any number ε > 0 we can find a δ > 0 such that f ( z ) − a < ε whenever 0 < z − a < δ . For the limit to exist, it must be independent of the direction in which we approach z = a. Note that a limit only exists if the limit is independent of the way that we approach the point in question, a point which is illustrated in Example 2.14. Limits in the theory of complex variables satisfy the same properties that limits do in the real case. Specifically, let us define lim f ( z ) = A z →a
lim f ( z ) = B z →a
Complex Variables Demystified
34 Then the following hold
lim { f ( z ) + g( z )} = lim f ( z ) + lim g( z ) = A + B
(2.11)
lim { f ( z ) − g( z )} = lim f ( z ) − lim g( z ) = A + B
(2.12)
z →a
z →a
z →a
z →a
z →a
{
z →a
}{lim g(z)} = AB
lim { f ( z ) g( z )} = lim f ( z ) z →a
lim z →a
z →a
z →a
f (z) A f ( z ) lim = z →a = g ( z ) lim g ( z ) B
(2.13)
(2.14)
z →a
Property in Eq. (2.14) holds as long as B ≠ 0. Limits can be calculated in terms of real and imaginary parts. Let f = u + iv, z = x + iy, and z0 = x 0 + iy0 , w = u0 + iv0 . Then lim f ( z ) = w0 z → z0
If and only if lim u( x , y) = u0 x → x0 y→ 0
lim v ( x , y) = v0 x → x0 y→ 0
(2.15)
OPEN DISKS Frequently, in complex analysis we wish to consider a circular region in the complex plane. We call such a region a disk. Suppose that the radius of the disk is a. If the points on the edge of the disk, that is, the points lying on the circular curve defining the border of the disk are not included in the region of consideration, we say that the disk is open. Consider a disk of radius one centered at the origin. We indicate this by writing z 0 and − π < θ < π . Is this function analytic? SOLUTION We write the function in terms of the polar representation: f ( z ) = z = reiθ = r eiθ / 2 Using Euler’s formula this can be written as f ( z ) = r eiθ / 2 = r cos(θ / 2) + i r sin(θ / 2) So we have u(r ,θ ) = r cos(θ / 2)
and
v (r ,θ ) = r sin(θ / 2)
Complex Variables Demystified
58 This means that
1 ∂u cos(θ / 2) = ∂r 2 r
r ∂u sin(θ / 2) =− 2 ∂θ
1 ∂v sin(θ / 2) = ∂r 2 r
∂v r = cos(θ / 2) ∂θ 2
Since we have the following relationships: r cos(θ / 2) = vθ 2 r uθ = − sin(θ / 2) = − rvr 2
rur =
The polar form of the Cauchy-Riemann equations are satisfied and the given function is analytic on the specified domain. In an analogous manner to Eq. (3.25), using the Cauchy-Riemann equations it can be shown that ∂v ⎞ ⎛ ∂u f ′( z ) = e − iθ ⎜ + i ⎟ ⎝ ∂r ∂r ⎠ EXAMPLE 3.10 Does the derivative of f ( z ) = 1/ z exist? If so what is f ′( z ) in polar form? SOLUTION First let’s write the function in polar form: f (z) =
1 1 1 = iθ = e − iθ z re r
Using Euler’s formula, we can split this into real and imaginary parts: 1 1 f ( z ) = cos θ − i sin θ r r Computing the derivatives we find ∂u 1 = − 2 cosθ ∂r r ∂v 1 = sin θ ∂r r 2
∂u 1 = − sin θ ∂θ r 1 ∂v = − cosθ r ∂θ
(3.28)
CHAPTER 3
Complex Derivatives
59
It’s apparent that these results satisfy r
∂u ∂v = ∂r ∂θ
and
−r
∂v ∂u = ∂r ∂θ
This means that the derivative exists, since the Cauchy-Riemann equations are satisfied (provided that r > 0). Using Eq. (3.28) we can find f ′(z). We obtain ∂v ⎞ i ⎛ ∂u ⎛ 1 ⎞ f ′( z ) = e − iθ ⎜ + i ⎟ = e − iθ ⎜ − 2 cos θ + 2 sin θ ⎟ ⎝ r ⎠ ⎝ ∂r ∂r ⎠ r e − iθ (cos θ − i sin θ ) r2 e − iθ = − 2 (e − iθ ) r e − i 2θ =− 2 r 1 1 = − 2 i 2θ = − 2 r e z =−
Some Consequences of the Cauchy-Riemann Equations Let’s take a step back and formally define the term analytic. We say that a function f ( z ) is analytic in an open set S if its derivative exists and is continuous at every point in S. If you hear a mathematician say that a complex function is regular or holomorphic, the meaning is the same. A function can’t be analytic if its derivative only exists at a point. If we say that f (z) is analytic at some point z0 then this means it is analytic throughout some neighborhood 2 of z0. So, recalling Example 3.7, while f ( z ) = z satisfies the Cauchy-Riemann equations at the origin, it is not analytic because it does not satisfy the CauchyRiemann equations at any point displaced from the origin (or at any nonzero point). As a result we cannot construct a neighborhood about the origin where the CauchyRiemann equations would be satisfied, so the function is not analytic.
Definition: Singularity Suppose that a function f ( z ) is not analytic at some point z0 , but it’s analytic in a neighborhood that contains z0 . In this case, we say that z0 is a singularity or singular
Complex Variables Demystified
60
point of f (z). Singularities will take center stage when we talk about power series expansions of complex functions.
Definition: Necessary and Sufficient Conditions for a Function to Be Analytic There are two necessary conditions a function f ( z ) must satisfy to be analytic. These are •
f ( z ) must be continuous
• The Cauchy-Riemann equations must be satisfied These conditions, however, are not sufficient to say a function is analytic. To satisfy the sufficiency condition for differentiability at a point z 0 , a function f ( z ) must satisfy the following conditions: • It must be defined throughout an ε -neighborhood of the point z0. • The first-order partial derivatives ux , u y , v x , and v y must exist everywhere throughout the ε -neighborhood. • The partial derivatives must be continuous at z0 and the Cauchy-Riemann equations must be satisfied.
SOME PROPERTIES OF ANALYTIC FUNCTIONS Let f ( z ) and g( z ) be two analytic functions on some domain D. Then • The sum and difference f ± g is also analytic in D. • The product f ( z ) g( z ) is analytic in D. • If g( z ) does not vanish at any point in D, then the quotient f ( z ) /g( z ) is analytic in D. • The composition of two analytic functions g[ f ( z )] or f [ g( z )] is analytic in D EXAMPLE 3.11 2 2 Determine whether or not the function f ( z ) = ( z + 1) /[( z + 2)( z + 3)] is analytic. SOLUTION Since z 2 + 1 and ( z + 2)( z 2 + 3) are both analytic (note there is no z dependence), and the quotient of two analytic functions is analytic, we conclude that f (z) is analytic. However, this is not true at any singular points of the function, which are points for which the denominator vanishes. The singular points in this case are z = −2
±i 3
CHAPTER 3
Complex Derivatives
61
So, we say that f (z) is analytic throughout the complex plane except at these points, which are the singularities of the function. An important theorem which is a consequence of the Cauchy-Riemann equations tells us if a function is constant in a domain D. THEOREM 3.3 If f ′( z ) = 0 everywhere in a domain D, then f (z) must be constant in D.
Harmonic Functions An important class of functions known as harmonic functions play an important role in many areas of applied mathematics, physics, and engineering. We say that a function u( x , y) is a harmonic function if it satisfies Laplace’s equation in some domain of the x-y plane: ∂2u ∂2u + =0 ∂x 2 ∂y 2
(3.29)
Here, we have assumed that u( x , y) has continuous first and second partial derivatives with respect to both x and y. An important application of harmonic functions in physics and engineering is in the area of electrostatics, for example. Harmonic functions also find application in the study of temperature and fluid flow. It turns out that the Cauchy-Riemann equations can help us find harmonic functions, as the next theorem illustrates. THEOREM 3.4 Suppose that f ( z ) = u( x , y) + iv ( x , y) is an analytic function in a domain D. If follows that u( x , y) and v ( x , y) are harmonic functions. PROOF The proof is actually easy. Since f (z) is analytic, then the Cauchy-Riemann equations are satisfied: ∂u ∂v = ∂x ∂y
and
∂v ∂u =− ∂x ∂y
Now let’s take the derivative of the first equation with respect to x: ∂2u ∂2 v = ∂x 2 ∂x ∂y
Complex Variables Demystified
62
Taking the derivative of the second Cauchy-Riemann equation with respect to y gives ∂2u ∂2 v = − ∂y∂x ∂y 2 Since partial derivatives commute (that is, their order does not matter) it is the case that ∂2 v ∂2 v = ∂x ∂y ∂y∂x From which it follows that ∂2u ∂2u = − ∂x 2 ∂y 2 ⇒
∂2u ∂2u + =0 ∂x 2 ∂y 2
So we’ve shown that if a function is analytic, then the real part u( x , y) satisfies Laplace’s equation. A similar procedure can be used to show that the imaginary part v ( x , y) is harmonic as well.
Definition: Harmonic Conjugate Suppose that u and v are two harmonic functions in a domain D. If their first-order partial derivatives satisfy the Cauchy-Riemann equations, then we say that v is the harmonic conjugate of u. THEOREM 3.5 A function f ( z ) = u( x , y) + iv ( x , y) is analytic if and only if v ( x , y) is the harmonic conjugate of u( x , y). EXAMPLE 3.12 Is u( x , y) = e − y sin x a harmonic function? If so write down an analytic function f ( z ) such that u is its real part. SOLUTION We compute the partial derivatives of u. We find ∂u = e − y cos x ∂x ∂u = − e − y sin x ∂y
∂2u = − e − y sin x 2 ∂x ∂2u ⇒ 2 = e − y sin x ∂y
⇒
CHAPTER 3
Complex Derivatives
63
It’s clear that the function is harmonic since ∂2u ∂2u = − e − y sin x + e − y sin x = 0 + ∂x 2 ∂y 2 Using the Cauchy-Riemann equations, we have ∂u ∂v = e − y cos x = ∂x ∂y ∂u ∂v = − e − y sin x = − ∂y ∂x So it must be the case that v ( x , y) = − e − y cos x. The analytic function we seek is therefore f ( z ) = u( x , y) + iv ( x , y) = e − y sin x − ie − y cos x
The Reflection Principle The reflection principle allows us to determine when the following condition is satisfied: f (z) = f (z )
(3.30)
If f ( z ) is analytic in a domain D that contains a segment of the x axis, then Eq. (3.30) holds if and only if f (x) is real for each point of the segment of x contained in D. EXAMPLE 3.13 Do f ( z ) = z + 1 and g( z ) = z + i satisfy the reflection principle? SOLUTION Since f ( x ) = x + 1 is a real number in all cases, the reflection principle is satisfied. In this simple example we can actually see this immediately since f ( z ) = z + 1 = z + 1 = f ( z ). In the second case, we have g( x ) = x + i, which is not a real number. The reflection principle is not satisfied which means that g( z ) ≠ g( z ). This function is also simple enough so that we can verify this explicitly—we have g( z ) = z + i = z − i , but g( z ) = z + i .
Complex Variables Demystified
64
Summary In this chapter, we learned how to determine if a function of a complex variable is differentiable or analytic. The necessary condition for a function to be analytic is that it be continuous and satisfy the Cauchy-Riemann equations. If a function is analytic, then its real and imaginary parts are harmonic functions, that is, they satisfy Laplace’s equation.
Quiz n 1. Let f ( z ) = z . Using the limit procedure outlined in Example 3.1, find f ′( z ). Δw 2 2. Let f ( z ) = z . Find . Does the derivative exist? Δz 3. Compute f ′( z ) when f ( z ) = 3z 8 − 6 z 2 + 4.
4. What is the derivative of f ( z ) =
(3 + 2 z )2 ? z2
z −1 ? z + iz − i + 1 6. Show that e z is not analytic using the Cauchy-Riemann equations. 5. What is lim z →1
2
7. Is f = x − iy differentiable at the origin? 8. Let f ( z ) = eiz. Is this function entire? 3 iθ / 3 9. Does f = re have a derivative everywhere in the domain r > 0, 0 < θ < 2π ? 10. Let u( x , y) = x 2 − y 2. Is this function harmonic? If so, what is the harmonic conjugate?
CHAPTER 4
Elementary Functions
In this chapter we introduce some of the elementary functions in the context of complex analysis. Our discussion will include polynomials, rational functions, the exponential and logarithm, trigonometric functions and their inverses, and finally, the hyperbolic functions and their inverses.
Complex Polynomials A polynomial is a function f ( z ) that can be written in the form f ( z) = a0 + a1z + a2 z 2 + + an z n
(4.1)
The highest power n is called the degree of the polynomial and a j are constants called coefficients. In general, the coefficients can be complex numbers.
Copyright © 2008 by The McGraw-Hill Companies, Inc. Click here for terms of use.
Complex Variables Demystified
66
Since z = x + iy , a complex polynomial can be viewed as a polynomial in the real variables x and y with complex coefficients. For example, consider f ( z ) = 5 − iz + 2 z 2
(4.2)
We can write this as f ( z ) = 5 − iz + 2 z 2 = 5 − i ( x + iy) + 2( x + iy)2 = 5 − ix + y + 2 x 2 + i 4 xy − 2 y 2 = 5 + 2 x 2 − 2 y 2 + y + i (4 xy − x ) Following the last chapter, we can identify u ( x , y) = 5 + 2 x 2 − 2 y 2 + y ⇒
∂u = 4x ∂x
∂u = −4 y + 1 ∂y
and v ( x , y) = 4 xy − x ∂v ⇒ = 4y −1 ∂x
∂v = 4x ∂y
Notice that u x = vy and u y = − vx , so this is an analytic function. We can also verify this by noticing that ∂f ∂ = (5 − iz + 2 z 2 ) = 0 ∂z ∂z We can generate some plots to look at the behavior of the function. When studying a complex function, you might want to plot its modulus and the real and imaginary parts to see where interesting features appear. Let’s plot f ( z ) = f ( z ) f ( z ). This is shown in Fig. 4.1. Obviously, the function has some interesting behavior around the origin. We see more by looking at the contour plot, shown in Fig. 4.2. The most interesting behavior seems to be around x = 0 . At this point, the real and imaginary parts of the function are given by u ( 0 , y) = 5 − 2 y 2 + y
v ( 0 , y) = 0
Plotting the modulus of f with x = 0 , we see the two zeros in y as shown in Fig. 4.3.
CHAPTER 4
Elementary Functions
67
10 8 6 4 2 0 –10
f (z)
10 5 0 y –5 x
–5
0 5 10 –10
Figure 4.1 A plot of f ( z ) =
f ( z ) f ( z ) for the function defined in Eq. (4.2).
4
2
0
–2
–4
–4
–2
0
2
4
2 Figure 4.2 A contour plot showing the modulus of f ( z ) = 5 − iz + 2 z .
Complex Variables Demystified
68
f (z)
12 10 8 6 4 2 –4
–2
2
y
4
Figure 4.3 A plot of the modulus of f ( z ) with x = 0.
You can also look at the real and imaginary parts to learn about the function. In Fig. 4.4, we show a plot of the real part of Eq. (4.2) and in Fig. 4.5, we show a contour plot of the real part of the function. A plot of the imaginary part of Eq. (4.2) and its contours are shown in Figs. 4.6 and 4.7, respectively.
10 8 6 Re f (z) 4 2 0 –10
10 5 0 y –5 –5
0 x
5 10 –10
Figure 4.4 The real part of f ( z ).
CHAPTER 4
Elementary Functions
69
4
2
0
–2
–4
–4
–2
0
2
4
Figure 4.5 A contour plot of the real part of f ( z ).
20 10 Im f (z)
0
2
–10 –20 0 –2 0 –2
x 2
Figure 4.6 The imaginary part of Eq. (4.2).
y
Complex Variables Demystified
70
4
2
0
–2
–4
–4
–2
0
2
4
Figure 4.7 A contour plot of the imaginary part of the function.
The Complex Exponential We have already seen the exponential function ez. In this section, we review some of it’s properties. Using z = x + iy we have already noted that the complex exponential can be written as ez = e x eiy
(4.3)
eiy = cos y + i sin y
(4.4)
Using Euler’s formula we have
Expanding out Eq. (4.3) we have the real and imaginary parts of the complex exponential: Re(e z ) = u( x , y) = e x cos y Im(e z ) = v ( x , y) = e x sin y
(4.5)
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Elementary Functions
71
2 1 Exp x cos y
0
5
–1 –2 0
0 y 0.25 0.5 x
–5
0.75 1
z Figure 4.8 A plot of the real part of e .
Looking at these functions, you can see that both the real and imaginary parts increase without bound as x → ∞. In Fig. 4.8, we show a plot of the real part of e z for 0 ≤ x ≤ 1, −2π ≤ y ≤ 2π . The oscillations due to the cos function in the y direction are readily apparent, as is the fact that the function is increasing rapidly in the x direction. z A contour plot of the real part of e is shown in Fig. 4.9. The oscillations along the y direction are apparent. The additive property of exponents, that is, ea eb = ea+b also carries over to the complex case. This is due to the way we add complex numbers. Let z1 = x1 + iy1 and z2 = x2 + iy2. Then we know that z1 + z2 = ( x1 + x 2 ) + i ( y1 + y2 ). Now we utilize the fact that exponents add for real numbers. That is: e z1 e z2 = e x1 +iy1 e x2 +iy2 = (e x1 eiy1 )(e x2 eiy2 ) = (e x1 e x2 )(eiy1 eiy2 ) = e x1 + x2 (eiy1 eiy2 )
Complex Variables Demystified
72
4
2
0
–2
–4
–4
–2
0
2
4
Figure 4.9 A contour plot of the real part of e z.
We can’t just assume the additive property holds for eiy1 eiy2. But we can show it does fairly easily: eiy1 eiy2 = (cos y1 + i sin y1 )(cos y2 + i sin y2 ) = cos y1 cos y2 − sin y1 sin y2 + i (sin y1 cos y2 + cos y1 sin y2 ) = cos( y1 + y2) + i sin( y1 + y2 ) = exp[i ( y1 + y2 )] So we’ve got e z1 e z2 = e x1 + x2 (eiy1 eiy2 ) = e x1 + x2 ei( y1 + y2 ) = e z1 + z2 It follows that e z1 = e z1 − z2 e z2 Using e0 = 1, you can deduce from Eq. (4.6) that 1/e z = e − z as in the real case.
(4.6)
CHAPTER 4
Elementary Functions
EXAMPLE 4.1 Evaluate exp[(1 + pi)/4]. SOLUTION We write this as exp ⎛⎜ ⎝
1+ πi ⎞ 1/ 4 iπ / 4 ⎟⎠ = e e = 4
4
e iπ / 4 (e ) 4
= 4 e (cos π / 4 + i sin π / 4) 1 ⎞ 4 1 ⎛ 1 = 4 e⎜ +i (1 + i ) ⎟= e ⎝ 2 2⎠ 2 EXAMPLE 4.2 z Find e . SOLUTION We have e z = e x +iy = e x eiy = e x (cos y + i sin y) So e z = e x (cos y + i sin y) = e x cos y + i sin y = ex ⋅ 1 = ex EXAMPLE 4.3 Show that ez is a periodic function with period 2kπ i , where k is an integer. SOLUTION We have e z + 2 kπ i = e z e 2 kπ i = e z (cos 2 kπ + i sin 2 kπ ) = ez
73
Complex Variables Demystified
74 EXAMPLE 4.4 What is the argument of e z?
SOLUTION In polar coordinates, a complex variable is written as z = reiθ Hence e z = e z eiθ z x for some θ which is arg(e z ). We have already seen in Example 4.2 that e = e . We also know that
e z = e x eiy z Therefore, comparing with e z = e z eiθ , we conclude that arg(e ) = y. But we aren’t quite done. Since the cosine and sin functions are 2π periodic, and eiy = cos y + i sin y, we can add any integer multiple of 2π to the argument without changing anything. So the argument is really given by
arg(e z ) = y + 2nπ
n = 0, ±1, ±2,…
You know from elementary calculus that the logarithm is the inverse, if you will, of the exponential. That is: eln x = x A similar function exists in complex variables. Due to the periodic nature of e z , we will see that the complex logarithm is a multivalued function. We define the natural logarithm in the following way. Let z = ew. Then w = ln z
(4.7)
CHAPTER 4
Elementary Functions
75
Now use the polar representation of z, namely, z = reiθ . Now we have w = ln z = ln(reiθ ) = ln r + ln eiθ = ln r + iθ
(4.8)
Using the fact that the cosine and sin functions are 2π periodic, the correct representation is actually w = ln r + i (θ + 2 kπ )
k = 0, ±1, ±2,...
(4.9)
A key aspect of definition in Eq. (4.9) is that the complex natural logarithm is a multivalued function. Definition in Eq. (4.8), for which k = 0, is called the principal value or the principal branch of ln z . In that case, we are restricting the argument to 0 ≤ θ < 2π . Note that this choice is not unique, all that is required is that we select an interval of length 2π . So it is equally valid to choose the principal branch for −π < θ ≤ π .
Trigonometric Functions You have already seen the use of trigonometric functions in the theory of complex variables. Here we state some familiar results for reference. First, we write the cosine and sin functions in terms of the complex exponential. This follows from Euler’s identity. You should already be familiar with these results: cos z =
eiz + e − iz 2
(4.10)
sin z =
eiz − e − iz 2i
(4.11)
The tangent function can be written in terms of exponentials using Eqs. (4.10) and (4.11): tan z =
eiz − e − iz sin z = − i iz e + e − iz cos z
(4.12)
Complex Variables Demystified
76
Likewise, we have the cotangent function which is just the reciprocal of Eq (4.12): cot z =
eiz + e − iz cos z = i iz e − e − iz sin z
(4.13)
The secant and cosecant functions can also be written down in terms of exponentials. These are given by sec z =
1 2 = iz cos z e + e − iz
(4.14)
csc z =
1 2i = iz sin z e − e− iz
(4.15)
All of the results from trigonometry using real variables carry over to complex variables. We illustrate this in the next two examples. EXAMPLE 4.5 Show that sin( x + iy) = sin x cos iy + cos x sin iy SOLUTION Using Euler’s identity: ei ( x+iy ) − e − i ( x+iy ) 2i ix − y e e − e − ix e y = 2i (cos x + i sin x )e − y − (cos x − i sin x )e y = 2i y −y i sin x (e + e ) cos x (e − y − e y ) + = 2i 2i i ( iy ) − i ( iy ) e +e ei ( iy ) − e − i ( iy ) + cos x = sin x 2 2i = sin x cos iy + cos x sin iy
sin( x + iy) =
CHAPTER 4
Elementary Functions
77
EXAMPLE 4.6 Show that cos 2 z + sin 2 z = 1. SOLUTION We start by writing z = x + iy and utilize the fact that cos 2 x + sin 2 x = 1, when x is a real variable. Using the result of the last example we have sin( x + iy) = sin x cos iy + cos x sin iy cos( x + iy) = cos x cos iy − sin x sin iy Therefore sin 2 z = (sin x cos iy + cos x sin iy)2 = sin 2 x cos 2 iy + cos 2 x sin 2 iy + 2 cos x sin x cos iy sin iy cos 2 z = (cos x cos iy − sin x sin iy)2 = cos 2 x cos 2 iy + sin 2 x sin 2 iy − 2 cos x sin x cos iy sin iy So it follows that cos 2 z + sin 2 z = sin 2 x cos 2 iy + cos 2 x sin 2 iy + 2 cos x sin x cos iy sin iy + cos 2 x cos 2 iy + sin 2 x sin 2 iy − 2 cos x sin x cos iy sin iy = cos 2 x cos 2 iy + sin 2 x cos 2 iy + cos 2 x sin 2 iy + sin 2 x sin 2 iy = cos 2 iy (cos 2 x + sin 2 x ) + sin 2 iy (cos 2 x + sin 2 x ) = cos 2 iy + sin 2 iy Now we expand each terms using Euler’s identity: ⎛ ei ( iy ) + e − i ( iy ) ⎞ cos iy = ⎜ ⎟⎠ ⎝ 2
2
2
2
e 2 y + e −2 y + 2 ⎛ e− y + e y ⎞ = =⎜ ⎝ 2 ⎟⎠ 4 and ⎛ ei ( iy ) − e − i ( iy ) ⎞ sin 2 iy = ⎜ ⎟⎠ ⎝ 2i 2
2
⎛ e 2 y + e −2 y − 2 ⎞ ⎛ e− y − e y ⎞ = − =⎜ ⎜⎝ ⎟⎠ ⎝ 2i ⎟⎠ 4
Complex Variables Demystified
78 Therefore cos 2 iy + sin 2 iy =
e2 y + e −2 y + 2 ⎛ e2 y + e −2 y − 2 ⎞ 1 1 −⎜ ⎟⎠ = 2 + 2 = 1 ⎝ 4 4
2 2 Hence, cos z + sin z = 1. Following real variables, the trigonometric functions of a complex variable have inverses. Let z = cos w . Then we define the inverse w = cos −1 z, which we call the arc cosine function or cosine inverse. There is an inverse trigonometric function for each of the trigonometric functions defined in Eqs. (4.10)–(4.15). The inverses are written in terms of the complex logarithm (see Example 1.8 for a derivation). The formulas are
1 cos −1 z = ln ( z + z 2 − 1 ) i
(4.16)
1 sin −1 z = ln ( iz + 1 − z 2 ) i
(4.17)
tan −1 z =
1 ⎛ 1 + iz ⎞ ln ⎜ ⎟ 2i ⎝ 1 − iz ⎠
(4.18)
1 ⎛ 1 + 1 − z2 ⎞ sec −1 z = ln ⎜ ⎟ i ⎝ z ⎠
(4.19)
1 ⎛ i + z2 − 1 ⎞ csc z = ln ⎜ ⎟ i ⎝ z ⎠
(4.20)
−1
cot −1 z =
1 ⎛ z +i⎞ ln ⎜ ⎟ 2i ⎝ z − i ⎠
(4.21)
The Hyperbolic Functions The complex hyperbolic functions are defined in terms of the complex exponential as follows: cosh z =
ez + e− z 2
(4.22)
CHAPTER 4
Elementary Functions
79
2 1 Cosh z
0
5
–1 –2 0
0 y 0.25 0.5 x
–5
0.75 1
Figure 4.10 A plot of cosh z with 0 ≤ x ≤ 1.
sinh z =
ez − e− z 2
(4.23)
These functions show some interesting features. Let’s take a closer look at cosh z. A plot of cosh z is shown in Fig. 4.10 focusing on the region 0 ≤ x ≤ 1. Note the oscillations along the y direction. These oscillations result from the fact that this function has trigonometric functions with y argument. To see this, we write the hyperbolic cosine function in terms of z = x + iy: ez + e− z 2 x + iy e + e − ( x+iy ) = 2 x e (cos y + i sin y) + e − x (cos y − i sin y) = 2
cosh z =
= cos y cosh x + i sin y sinh x
Complex Variables Demystified
80
20 15 10 Cosh z
5
5 0 0 y
–4 –2 0 x
–5
2 4
Figure 4.11 Looking at cosh z over a wider region, we see that the oscillations sit in a region which is surrounded by exponential growth on both sides.
From here, we see that the modulus is given by cosh z = cos 2 y cosh 2 x + sin 2 y sinh 2 x These oscillations actually sit inside a kind of half-pipe. This is shown in Fig. 4.11. To see what’s happening, consider a plot of cosh 2 x + sinh 2 x . The function quickly grows out of control, as shown in Fig. 4.12. If we look at the real part of cosh z alone, the oscillations are stronger. Compare Fig. 4.13, which shows the real part of the function, to Fig. 4.11, which shows the modulus over the same region. The differences are also apparent in the contour plots, which are shown side by side in Fig. 4.14. The oscillations are highly visible in the contour plot of the real part of the function, shown on the right. The reason that the oscillations appear more prominent in plots of the real part of the function is that we have cosh z = cos y cosh x + i sin y sinh x
CHAPTER 4
Elementary Functions
81
3000 2500 2000 1500 1000 500 –4
–2
2
4
x
Figure 4.12 A plot of cosh 2 x + sinh 2 x , with exponential growth for positive and negative values of x.
So the exponential growth of the real part of the function is governed by cosh x, which blows up much slower than cosh 2 x + sinh 2 x . A plot of cosh x is shown over the same interval in Fig. 4.15 for comparison with Fig. 4.12. Be sure to compare the vertical axis of the two plots.
20 15 Re cosh z
10
5
5 0 0 y
–4 –2 0 x
–5
2 4
Figure 4.13 The real part of cosh z.
Complex Variables Demystified
82
4
4
2
2
0
0
–2
–2
–4
–4 –4
–2
0
2
–4
4
–2
Cosh z
0 2 Re (cosh z)
4
Figure 4.14 Contour plots of the modulus (on the left) and real part (on the right) of cosh z.
Several relations exist which correlate the hyperbolic and trig functions for complex arguments. These include cosh iz = cos z
(4.24)
sinh iz = i sin z
(4.25)
cos iz = cosh z
(4.26)
sin iz = i sinh z
(4.27)
40 30 20 10 –4
–2
2
4
x
Figure 4.15 The real part of cosh z is influenced heavily by cosh x.
CHAPTER 4
Elementary Functions
83
These formulas are very easy to derive. For example: sin iz =
e− z − ez ez − e− z ei ( iz ) − e − i ( iz ) = −i =i = i sinh z 2i 2 2
The following identities, carried over from real variables, also hold cosh( − z ) = cosh z
(4.28)
sinh( − z ) = − sinh z
(4.29)
cosh 2 z − sinh 2 z = 1
(4.30)
sinh( z + w) = sinh z cosh w + cosh z sinh w
(4.31)
cosh( z + w) = cosh z cosh w + sinh z sinh w
(4.32)
The following identities incorporate trigonometric functions: sinh z = sinh x cos y + i cosh x sin y
(4.33)
cosh z = cosh x cos y + i sinh x sin y
(4.34)
sinh z = sinh 2 x + sin 2 y
(4.35)
cosh z = sinh 2 x + cos 2 y
(4.36)
2
2
The hyperbolic functions are periodic. Looking at definitions in Eqs. (4.33) and (4.34), we see that this is due to the fact sinh z and cosh z that incorporate the trigonometric functions cosine and sin directly in their definitions. Therefore the period of the hyperbolic functions is given by 2π i
(4.37)
The zeros of the hyperbolic functions are given by cosh z = 0
π if z = ⎛⎜ + nπ ⎞⎟ ⎝2 ⎠
n = 0, ±1, ±2,...
(4.38)
sinh z = 0
if z = nπ i
n = 0, ±1, ±2,...
(4.39)
Complex Variables Demystified
84
We can also define the other hyperbolic functions analogous to the tangent, cosecant, and secant functions. In particular: tanh z =
ez − e− z ez + e− z
(4.40)
sech z =
2 e + e− z
(4.41)
csch z =
2 e − e− z
(4.42)
z
z
With the analogous identities (4.43)
1 − tanh 2 z = sech 2 z tanh( z ± w) =
tanh z ± tanh w 1 ± tanh z tanh w
(4.44)
The hyperbolic functions also have inverses. Like the trigonometric functions, these inverses are defined using logarithms. Since the inverses are defined in terms of logarithms they are multivalued functions. These are given by
(
)
(4.45)
(
)
(4.46)
cosh −1 z = ln z + z 2 − 1 sinh −1 z = ln z + z 2 + 1 tanh −1 z =
1 ⎛ 1+ z ⎞ ln ⎜ ⎟ 2 ⎝1− z⎠
(4.47)
Complex Exponents α Consider a function f ( z ) = z , where α is a complex number. This function can be written in a convenient form using the exponential and natural log as follows:
f ( z ) = z α = eα ln z
(4.48)
CHAPTER 4
Elementary Functions
85
This can be generalized to the case when the exponent of a function is another complex function, that is, f ( z ) g ( z ) = e g ( z )ln[ f ( z )]
(4.49)
From these definitions, we can see that powers of a complex variable z are multivalued functions. EXAMPLE 4.7 Consider i i and determine if it is multivalued. SOLUTION Using Eq. (4.48) we write i i = exp(i ln i) Now
π π ln i = ln (1 ⋅ eiπ / 2 ) = ln 1 + i ⎛⎜ + 2nπ ⎞⎟ = i ⎛⎜ + 2nπ ⎞⎟ ⎠ ⎝2 ⎠ ⎝2
for n = 0, ±1, ±2,...
where Eq. (4.9) was used. So we have ⎛ ⎡ π ⎤⎞ ⎛ π ⎞ i i = exp(i ln i ) = exp ⎜ i ⎢i ⎛⎜ + 2nπ ⎞⎟ ⎥ ⎟ = exp ⎜ − ⎛⎜ + 2nπ ⎞⎟ ⎟ ⎠ ⎦⎠ ⎠⎠ ⎝ ⎝2 ⎝ ⎣ ⎝2 where n = 0, ±1, ±2,..., demonstrating that this is a multivalued function—in fact it has infinitely many values. Interestingly, they are all real numbers. Consider n = 0 for which i i = exp(π /2) = 4.81.
Derivatives of Some Elementary Functions In Chap. 3, we have already studied derivatives in detail. In this section, we list some derivatives of the elementary functions for reference. Given a polynomial f ( z ) = a0 + a1z + a2 z 2 + + an z n
Complex Variables Demystified
86 The derivative is given by
df = a1 + 2a2 z + + nan z n −1 dz The derivative of the exponential function ez is d z e = ez dz
(4.50)
This result holds for the entire complex plane. Therefore the exponential function is analytic everywhere or we can say that it is entire. The derivative of the logarithm is a bit more tricky. If we define ln z = ln r + iθ where θ is restricted to the domain α < θ < α + 2π , then we have a single-valued function with real and imaginary parts given by u = ln r
v =θ
These functions satisfy the Cauchy-Riemann equations, since ∂u 1 = ∂r r ∂u ∂v r = ∂r ∂θ
∂v =1 ∂θ
and ∂v ∂u = −r = 0 ∂r ∂θ Given that the Cauchy-Riemann equations are satisfied, we can use Eq. (3.28), which stated that ∂v ⎞ ⎛ ∂u f ′( z ) = e − iθ ⎜ + i ⎟ ⎝ ∂r ∂r ⎠ So we’ve got ∂v ⎞ 1 d 1 ⎛ ∂u ln z = e− iθ ⎜ + i ⎟ = e− iθ ⎛⎜ + i 0 ⎞⎟ = iθ ⎝ ⎠ ⎝ ∂r r ∂r ⎠ re dz
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That is, the derivative of the natural logarithm for complex variables is the same as that in the calculus of real variables, namely: 1 d ln z = dz z
(4.51)
This result is valid when z > 0 and α < arg z < α + 2π . The derivatives of the trigonometric functions also correspond to the results we expect. Let’s derive one example and then just state the other results. You can show that cos z = cos( x + iy) = cos x cosh y − i sin x sinh y So we have u( x , y) = cos x cosh y and v ( x , y) = − sin x sinh y. Then ∂u = − sin x cosh y ∂x
∂u = cos x sinh y ∂y
∂v = − cos x sinh y ∂x
∂v = − sin x cosh y ∂y
So it follows that ∂u ∂v = ∂x ∂y
∂u ∂v =− ∂y ∂x
Since the Cauchy-Riemann equations are satisfied, we can write ∂v ∂u +i ∂x ∂x = − sin x cosh y − i cos x sinh y
f ′( z ) =
But sin z = sin( x + iy) = sin x cosh y + i cos x sinh y , therefore: d cos z = − sin z dz
(4.52)
You can also derive this very easily using the exponential representation of the sin and cosine functions. Other results can be derived similarly: d sin z = cos z dz
(4.53)
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Since the exponential function is entire, the cosine and sin functions are also entire. Other derivatives follow from elementary calculus: d tan z = sec 2 z dz
d cot z = − csc 2 z dz
(4.54)
d sec z = sec z tan z dz
d csc z = − csc z cot z dz
(4.55)
The derivatives of the hyperbolic functions can be derived easily using exponential representations: d cosh z = sinh z dz
d sinh z = cosh z dz
(4.56)
d tanh z = sech 2 z dz
(4.57)
d sech z = −sech z tanh z dz
(4.58)
Finally, we note the derivative of a complex exponent: d α z = α zα −1 dz
(4.59)
Note, however, that since this is a multivalued function, this holds for z > 0, 0 < arg z < 2π or some other interval.
Branches A multivalued function repeats itself when z moves in a complete circle about the origin in the complex plane. When 0 ≤ θ < 2π , the function is single valued. We say that we are on one branch of the function. But as we let z traverse the circle again so we enter the region where 2π < θ , the function repeats. We say that we’ve entered another branch of the function. A multivalued function like this repeats itself any number of times. For convenience, a barrier is set up at our choosing in the complex plane where we do not allow z to cross. This barrier is called a branch cut. The point from which the branch cut originates is called a branch point. The branch cut extends out from the branch point to infinity. For example, for a multivalued function, we can take the branch point to be the origin and the branch cut can extend out from the origin to positive infinity (Fig. 4.16).
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0
Figure 4.16 Some multivalued functions repeats themselves after z has completely gone around the origin. We prevent the function from being multivalued by staying on one branch. This means we cannot cross the branch cut, which we have chosen in this case to be the line from the origin to positive infinity. Note that a circle does not have to be used, we just have to let z go completely around the origin—a circle was used here for simplicity.
Summary In this chapter, we described the basic properties of some elementary functions encountered in complex variables. These included polynomials, the complex exponential, the trig functions, the logarithm, the hyperbolic functions, and functions with complex exponents.
Quiz 1. Prove that cos( x + iy) = cos x cos iy − sin x sin iy. 2. If f ( x ) = e x, then f can never be negative. Is the same true of e z? 3. Find a compact expression for e2+3π i. 4. Find an identity for 1 + tan 2 z by using Eq. (4.12). 5. Find an identity for tan( z + w). 6. Are the inverse trig functions multivalued?
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CHAPTER 5
Sequences and Series
It is common practice and often a necessity to represent a function of a real variable using an infinite series expansion. It turns out that this is also true when working with complex functions. As we will see, there are some new concepts involved when working with complex functions. We begin by considering sequences.
Sequences Consider the positive integers n = 1, 2, 3,... and consider a function on the positive integers, which we denote by f (n). We call such a function a sequence. The output of the function is a number: f (n) = an . So a sequence is an ordered set of numbers a1 , a2 , a3 ,... and we refer to an as the nth term in the sequence. Sequences can also be indicated using curly braces, so we can write { f (n)} or {an }.
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THE LIMIT OF A SEQUENCE It is desirable to find the limit of an infinite sequence to determine whether or not the sequence converges or approaches a specific finite value as n goes to infinity. Limits of sequences are defined in the standard way. Suppose that the limit of a sequence f (n) = an is . Then this means that, given any positive number ε we can find a number N depending on ε such that
an − < ε
for all n > N
(5.1)
Using standard notation you are familiar with from calculus, we can write lim an =
(5.2)
n→∞
If the limit of a sequence exists, we say that the sequence is convergent. If the limit does not exist or is infinite, then the sequence is divergent. Note that the limit of a given sequence is unique. The limits of sequences satisfy all of the standard properties you are familiar with from your study of the limits of functions. Let us denote two sequences an and bn such that lim an = A and lim bn = B . Then n→∞
n→∞
lim (an ± bn ) = A ± B n→∞
(
)(
)
lim an bn = lim an lim bn = AB n→∞
n→∞
n →∞
(5.3)
lim an
an n→∞ A = = n→∞ b lim bn B n
lim
n→∞
The last result holding provided that B ≠ 0.
SEQUENCES OF COMPLEX FUNCTIONS So far we haven’t said anything about complex variables—we’ve just sketched out the notion of sequences in general. These ideas can be carried over to complex functions fn ( z ) defined on some region R of the complex plane. If f ( z ) exists and is finite, and lim fn ( z ) = f ( z ) n→∞
(5.4)
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on R we say that the sequence fn ( z ) converges to f ( z ) on R. The formal definition of this limit follows from Eq. (5.1). That is, given any ε > 0 there exists an N depending on ε such that fn ( z ) − f ( z ) < ε
(5.5)
for n > N . If the limit does not exist or is infinite, then the sequence is divergent. EXAMPLE 5.1 Let a sequence zn be defined as zn =
2 + 3i n2
Does this sequence converge? Find an N such that Eq. (5.5) is satisfied. SOLUTION We examine the limit of this sequence. We have 2 2 + 3i = lim 2 + lim 3i = 0 + 3i = 3i 2 n→∞ n n→∞ n n→∞
lim zn = lim n→∞
That is, the sequence converges and its limit is 3i. Formally, given any ε > 0 we need to find an N such that (2 /n 2 ) + 3i − 3i = 2 / n 2 < ε for n > N . So we have 2 2
2 ε n This means that Eq. (5.5) is satisfied if we take N=
2 ε
Note that since N depends on ε , the sequence is not uniformly convergent (see Sec. “Uniformly Converging Series” later in the chapter).
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Infinite Series By summing up the individual terms in a sequence we can construct a series. This can be done using so-called partial sums. That is, let {an ( z )} be some complex sequence. Then we can form partial sums as follows: S1 = a1 ( z ) S2 = a1 ( z ) + a2 ( z ) Sn = a1 ( z ) + a2 ( z ) + + an ( z ) So, the nth partial sum is constructed by adding up the first n terms of the sequence. If we let n → ∞, we obtain an infinite series: ∞
∑ a (z)
(5.6)
lim Sn ( z ) = S ( z )
(5.7)
n
n =1
If the following condition holds: n→∞
where S ( z ) is a finite quantity we say that the series is convergent. If Eq. (5.7) does not hold then the series is divergent. A necessary but not sufficient condition for a series to be convergent is that the following condition holds: lim an ( z ) = 0 n→∞
(5.8)
In the next section, we’ll review some tests that can be used to determine whether or not a series converges.
Convergence An important concept used in working with series in complex analysis is the radius of convergence R. Simply put, we want to know over what region R of the complex plane does the series converge. It may be that the series converges everywhere, or it could turn out that the series only converges inside the unit disc, say.
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First let’s take a look at sequences again. If each term in a sequence is larger than or equal to the previous term, which means that an+1 ≥ an We say that the sequence is monotonic increasing. On the other hand, if an+1 ≤ an then the sequence is monotonic decreasing. If each term in the sequence is bounded above by some constant M: an < M
(5.9)
then we say that the sequence is bounded. A bounded monotonic sequence (either increasing or decreasing) converges.
CAUCHY’S CONVERGENCE CRITERION Saying that a sequence converges is the same as saying that it has a limit, so we can formalize the notion of convergence. Leave it up to Cauchy to have done that for us. So, {an } converges if given an ε > 0 we can find an N such that am − an < ε
for m, n > N
Cauchy’s convergence criterion is necessary and sufficient to show convergence of a sequence.
CONVERGENCE OF A COMPLEX SERIES Remember that any complex function f ( z ) can be written in terms of real and imaginary parts, just like a complex number. The real and imaginary parts are themselves real functions. So one way to check convergence is to check the convergence of the real and imaginary parts—assuming we have a series representation available—and seeing if they converge. So a necessary and sufficient condition that a series of the form ∑ a j + ib j converges is that the two series ∑ a j and ∑ b j both converge.
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Convergence Tests The following convergence tests can be used to evaluate whether or not a series converges. If we say that a series ∑ an converges absolutely, we mean that ∞
∑a
n
(5.10)
n=1
converges. The first test that we can apply for convergence is the comparison test. The comparison test tells us that if ∑ bn converges and an ≤ bn , then the series ∑ an converges absolutely. If ∑ bn diverges and an ≥ bn , the series ∑ an also diverges. However, we can’t say anything about the series ∑ an. The ratio test is a nice test that appeals to common sense. We take the ratio of the terms an+1 to an and take the limit n → ∞. Let
lim
n→∞
an+1 =R an
(5.11)
There are two possibilities: • If R < 1 then the series converges absolutely. • If R > 1 then the series is divergent. If R = 1then no information is available from the test. The nth root test checks the limit: lim n an = R n→∞
(5.12)
The possibilities here are the same we encountered with the ratio test. These are • If R < 1 then the series converges absolutely. • If R > 1 then the series is divergent. If R = 1then no information is available from the test.
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Raabe’s test checks the limit: ⎛ a ⎞ lim n ⎜ 1 − n+1 ⎟ n→∞ an ⎠ ⎝
(5.13)
Again • If R < 1 then the series converges absolutely. • If R > 1 then the series is divergent. If R = 1then no information is available from the test. Finally, we consider the Weierstrass M-test. Suppose that an ( z ) ≤ M n . If M n does not depend on z in some region of the complex plane where an ( z ) ≤ M n holds and ∑ M n converges, then ∑ an ( z ) is uniformly convergent.
Uniformly Converging Series We often find in the limits we compute that N depends on ε . When a series is uniformly convergent, then for any ε > 0 there is an N not depending on ε such that an ( z ) − R < ε for n > N , where R is the limit. That is, if the same N holds for all z in a given region D of the complex plane, then we say that the convergence is uniform.
Power Series A series that can be written as ∞
a0 + a1z + a2 z 2 + = ∑ an ( z − z0 )n
(5.14)
n=0
where the an are constants is called a power series. When the series converges for z − z0 < R we say that R is the radius of convergence. The series diverges if z − z0 > R. For z − z0 = R , the series may converge or it may diverge. Often in complex analysis, the region over which the series converges is a disc so the term radius has a literal geometric interpretation.
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Taylor and Maclaurin Series Suppose that a complex function f ( z ) is analytic in some region of the complex plane and let z0 be a point inside that region. Then f ( z ) has a power series expansion with expansion coefficients calculated by computing derivatives of the function at that point, giving the Taylor series expansion of the function: f ( z ) = f ( z0 ) + f ′( z0 )( z − z0 ) +
f ′′( z0 ) ( z − z0 )2 2!
f ( n ) (z0 ) ( z − z0 )n + + + n!
(5.15)
If we set z0 = 0, that is take the series expansion about the origin, we have a Maclaurin series.
Theorems on Power Series The most important fact about a convergent power series you should file away in your mind is that within the radius of convergence, you can differentiate a power series term by term, or you can integrate it term by term along any curve that lies within its radius of convergence (see Chaps. 6 and 7). EXAMPLE 5.2 Find the Taylor expansion of f ( z ) = 1/(1 − z + z 2 ) about the origin. SOLUTION We will calculate the first two derivatives. First, note that f (0) =
1 =1 1 − 0 + 02
The first derivative is d 1 1 =− (−1 + 2 z ) 2 dz 1 − z + z (1 − z + z 2 )2 ⇒ f ′(0) = 1 f ′( z ) =
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The second derivative is f ′′( z ) =
d ⎛ 1 ⎞ − ( −1 + 2 z )⎟ ⎜ ⎠ dz ⎝ (1 − z + z 2 )2
2 2 ( −1 + 2 z )2 − 2 3 (1 − z + z 2 )2 (1 − z + z ) f ′′(0) = 0 =
Finally, the third derivative is
f ′′′( z ) =
2 d ⎡ 2 ⎤ ( −1 + 2 z )2 − 2 3 2 2⎥ ⎢ dz ⎣ (1 − z + z ) (1 − z + z ) ⎦
6( −1 + 2 z )3 12( −1 + 2 z ) + (1 − z + z 2 )4 (1 − z + z 2 )3 f ′′(0) = −6 =−
So we have f ( z ) = f (0) + z f ′ (0) +
z2 z3 f ′′(0) + f ′′′(0) + 2! 3!
= 1 + z − z3 + EXAMPLE 5.3 Use the Weierstrass M test to determine whether or not the series ∑ an cos nx + bn sin nx converges, provided that the series ∑ an and ∑ bn converge and if x ∈[ −π , π ]. SOLUTION The values of cos nx and sin nx may be positive, negative, or zero. However, we know that they are bounded by 1, that is for all n: cos nx ≤ 1
and
sin nx ≤ 1
an cos nx ≤ an
and
bn sin nx ≤ bn
It follows that
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Now, since the series ∑ an and ∑ bn converge, given ε > 0 and n ≥ m: am + bm + am+1 + + an + bn < ε We then have am cos mx + bm sin mx + + an cos nx + bn sin nx ≤ am + bm + am+1 + + an + bn < ε We have thus constructed a series of numbers that converges ∑ an + bn for which ak + bk ≥ ak cos kx + bk sin kx for all x ∈[ −π , π ]. By the Weierstrass M test, ∑ an cos nx + bn sin nx is uniformly convergent. Since cos nx and sin nx are periodic with period 2π , the series is uniformly convergent for − ∞ < x 0 . Determine the radius of convergence. SOLUTION To find the radius of convergence for this series we use the root test: lim n an = L n→∞
In this case we’ve got
lim n an = lim n n(log n)a n→∞
n→∞
= lim exp ⎡ n n(log n)a ⎤ ⎣ ⎦ n→∞ a ⎤ ⎡1 = lim exp ⎢ log n + log(log n) ⎥ = e 0 = 1 n→∞ n ⎦ ⎣n Hence the radius of convergence is R = 1. EXAMPLE 5.10 Describe the convergence of the series: ∞
zn ∑ 2 n n =1 n (1 − z ) SOLUTION First, consider the case where z n = 1. It is clear that this will cause the series to blow up. This means that the nth roots of unity are not permitted for this series, that is z ≠ e 2π ik / n
for n ≥ 1
k = 0,1, 2,..., n − 1
So we conclude the series is divergent for z = 1. Now we check the case of z < 1. Notice that since z < 1: zn = 1 − zn
1 zn = 1. It is easy to see that the series converges in this case since
zn 1 n = → 1 as z → ∞ n 1 1− z −1 zn EXAMPLE 5.11 ∞ n −1 Describe the convergence of the series F ( z ) = ∑ n=1 [(−1) /(n + z )]. SOLUTION Notice that since the series contains z and not z, the series is actually a series of real numbers. Suppose that we pick some arbitrary z ∈. Then we can pick a k that satisfies k ≤ z < k +1 ⇒ n + k ≤ n + z < n + k +1 Which means that 1 1 1 < ≤ n + k +1 n + z n + k It follows that ∞
∞ ∞ 1 1 1 = < ∑ ∑ ∑ n =1 n + k + 1 m= k +2 m n =1 n + z
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Now, ∑ ∞m= k +2 (1/m) is the tail of the harmonic series, which is divergent. ∞ n −1 Therefore the series ∑ n=1[(−1) /(n + z )] does not converge absolutely. However, the series does converge. Notice that ( −1)n −1 =0 n→∞ n + z
lim Furthermore, it is the case that an+1 =
1 1 ≤ an = n +1+ z n+ z
Since lim an = 0 , the series converges (but not absolutely, as we’ve already n→∞ established). Now we investigate whether or not it converges uniformly. Consider the sum ( −1)n −1 F ( z ) − F2 N −1 ( z ) = ∑ n=2 N n + z ∞
Let n = 2 k , ⇒ k = n / 2 and for n = 2 N , k = N . So we can write (−1)2 k −1 k= N 2k + z ∞
F ( z ) − F2 N −1 ( z ) = ∑
∞ ⎛ 1 ⎞ 1 = ∑⎜ − 2 k + z ⎟⎠ k= N ⎝ 2k + 1 + z ∞
1 k = N (2 k + 1 + z )(2 k + z )
= −∑ ∞
∞ 1 1 1 < ∑ = N k = N (2 k + 1)(2 k ) n = 2 N n(n + 1)
≤∑
Therefore, it is possible to choose a positive integer M such that F ( z ) − Fn ( z ) < ε So the series converges uniformly.
for all n > M
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EXAMPLE 5.12 ∞ n 2 Let the domain of definition D be the unit disc and show that ∑ n=1 nz = z /(1 − z ) . SOLUTION You can check to see if the series converges inside the unit disc. Since it does, we can differentiate it term by term. Let’s recall the geometric series in Eq. (5.21): ∞
∑r
=
n
n= 0
1 1− r
Notice what happens if we take the derivative with respect to r of both sides: ∞ ∞ d ∞ n d n = = r r nr n −1 ∑ ∑ ∑ dr n =0 dr n=0 n =1 1 d 1 = dr 1 − r (1 − r)2
This demonstrates that ∞
∑ nr
n −1
=
n =1
1 (1 − r )2
The geometric series is convergent provided that r < 1. In the complex plane, this is the same as saying that z lies in the unit disc. Hence ∞
∑ nz
n −1
=
n =1
1 (1 − z )2
Now multiply both sides by z to obtain the desired result: ∞
∑ nz n=1
n
=
z (1 − z )2
Laurent Series A Laurent series is a serial representation of a function of a complex variable f ( z ). A major difference you will notice when comparing a Laurent series to a Taylor series or power series expansion is that a Laurent series includes terms with negative powers.
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In principle, the powers can range all the way down to −∞, but in many if not most cases only a few terms with negative power are included. So, generally speaking, the Laurent series of a complex function f ( z ) about the point z = z0 is given by f (z) =
∞
∑ a (z − z ) n
(5.25)
n
0
n =−∞
The coefficients in the expansion are calculated using Cauchy’s integral formula, which we discuss in the Chaps. 6 and 7. Stating it for the record: an =
1 f ( z )dz ∫ 2π i ( z − z0 )n+1
for n = 0,1, 2, ...
(5.26)
The integral is taken along curves defining an annulus enclosing the point z0. In Eq. (5.26), the curve used for the integration is the outer curve defining the annulus. The negative coefficients in the series are calculated using an =
1 n −1 ∫ f (z) (z − z0 ) dz 2π i
for n = 1, 2, 3,...
(5.27)
In this case the inner curve is used (see Fig. 5.1). By the deformation of path theorem, we know that we can use any concentric circle enclosing the singular point z0 to calculate the integral. As a result, formula in Eq. (5.26) is universally valid for n = 0, ±1, ±2,... A Laurent series can be written in the form f ( z ) = a0 + a1 ( z − z0 ) + a2 ( z − z 0 )2 + +
a−1 a−2 + + z − z0 ( z − z0 )2
(5.28)
C2
• z0
C1
Figure 5.1 An illustration of an annular region used for integration in the determination of the coefficients of a Laurent expansion.
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The summation including the terms with negative indices is called the principal part of the series: a−1 a−2 + + z − z0 ( z − z0 )2
(5.29)
We call the points z0 that give rise to terms with inverse powers of z − z0 in a Laurent expansion singular points or singularities. Colloquially speaking, singularities represent points at which a function will blow up. It is also a point at which the function is not differentiable. The analytic part of the series is given by the part of the expansion, which resembles an ordinary power series expansion: a0 + a1 ( z − z0 ) + a2 ( z − z0 )2 +
(5.30)
Types of Singularities The first type of singularity we encounter is called a removable singularity, because it is a point z = z0 at which the function appears to blow up, but at which a formal calculation lim f ( z ) exists. The quintessential example (which we will remind you z → z0 f ( z ) = 1. of again in Chap. 7) is f ( z ) = (sin z )/z . The value f (0) is not defined, but lim z→ If you grasp this then you understand the concept of the removable singularity. Suppose that the principal part of a Laurent series only has a finite number of terms: a− n a−1 a−2 + + + 2 z − z0 (z − z0 ) ( z − z0 )n
(5.31)
Then the point z = z0 is called a pole of order n. A pole causes the function to blow up at z = z0 . If a−1 is the only nonzero coefficient in the principal part of the series, we say that z = z0 is a simple pole. An essential singularity is one which results in an infinite number of inverse power terms in the Laurent expansion. That is, the principal part of the Laurent expansion is nonterminating. A branch point z = z0 is a point of a multivalued function where the function changes value when a curve winds once around z0 .
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A singularity at infinity is a zero of f ( z ) if we let z = 1/w and then consider the function F ( w) = f (1/z ).
Entire Functions We first met the concept of an entire function in Chap. 3. Now that we have introduced the concept of a Laurent series, we have a systematic way to determine if a function is entire. An entire function is analytic throughout the entire complex plane. The Laurent expansion of an entire function cannot contain a principal part. Or expressed another way, an entire function has a Taylor series expansion with an infinite radius of convergence. The radius of convergence is infinite since the function is analytic on the entire complex plane.
Meromorphic Functions A meromorphic function is analytic everywhere in the complex plane except at a finite number of poles. EXAMPLE 5.13 3 Describe the singularities of f ( z ) = 1/[( z − 2)( z + 4) ]. Is this function entire? SOLUTION The function f ( z ) has singularities at z = 2 and z = −4 . The pole at z = 2 is a simple pole because the power of this term is −1. The pole at z = −4 is a pole of order 3. The function is not entire, because it is not analytic at the poles. Since there are a finite number of poles, the function is meromorphic. EXAMPLE 5.14 Suppose that f ( z ) = ( z − 1)cos[1/ (z + 2)] . Find the Laurent expansion of this function about the point z = −2 and describe the nature of any singularities. Identify the analytic and principal parts of the series expansion. SOLUTION Recall the power series expansion of the cosine function: 1 1 1 cos z = 1 − z 2 + z 4 − z 6 + 2 4! 6!
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Now let w = z + 2 to simplify notation. Then 2
4
6
1 1 1 1 1 1 1 ⎛ 1 ⎞ = cos ⎛⎜ ⎞⎟ = 1 − ⎛⎜ ⎞⎟ + ⎛⎜ ⎞⎟ − ⎛⎜ ⎞⎟ + cos ⎜ ⎟ ⎝ w⎠ ⎝ z + 2⎠ 2 ⎝ w⎠ 4! ⎝ w ⎠ 6! ⎝ w ⎠ The term z − 1 = w − 3 and so 1 ⎛ 1 ⎞ f ( z ) = ( z − 1) cos ⎜ = ( w − 3) cos ⎛⎜ ⎞⎟ ⎝ w⎠ ⎝ z + 2 ⎟⎠ ⎛ 1 1 2 1 1 4 1 1 6 ⎞ = ( w − 3) ⎜ 1 − ⎛⎜ ⎞⎟ + ⎛⎜ ⎞⎟ − ⎛⎜ ⎞⎟ + ⎟ ⎝ ⎠ ⎝ ⎠ ⎝ ⎠ 2 w 4! w 6! w ⎝ ⎠ 2
2
4
4
3 1 1 1 3 1 1 1 = w − 3 − w ⎛⎜ ⎞⎟ + ⎛⎜ ⎞⎟ + w ⎛⎜ ⎞⎟ − ⎛⎜ ⎞⎟ + ⎝ ⎠ ⎝ ⎠ ⎝ ⎠ 4! ⎝ w ⎠ 2 w 2 w 4! w 1 3 1 3 − + = w−3− + + 2w 2w 2 4! w3 4! w 4 1 3 1 3 = z −1− + + − + 2 3 2( z + 2) 2( z + 2) 4 !( z + 2) 4 !( z + 2)4 Terms of the form ( z + 2) − n go on forever in this series, so the point z = −2 is an essential singularity. The analytic part of the Laurent expansion is z −1 The principal part of the Laurent expansion is −
1 3 1 3 + + − + 2 3 2( z + 2) 2( z + 2) 4 !( z + 2) 4 !( z + 2)4
EXAMPLE 5.15 z Given that f ( z ) = 1 /(e − 1) = (1 /z ) − (1 /2) + (1 /12) z + , describe the nature of any singularities and write down the analytic and principal parts of the expansion. Is the function entire? SOLUTION The function is not entire because it has a singularity at z = 0. Since this is the only singular point, the function is meromorphic. The principal part of the Laurent expansion includes the single term 1 z
Complex Variables Demystified
114 The analytic part is given by
1 1 − + z + 2 12 EXAMPLE 5.16 2 2 What are the singular points of f ( z ) = 3/( z + a ). SOLUTION Notice that f (z) =
3 3 = 2 z +a ( z + ia)( z − ia) 2
Therefore the function has two isolated singular points at z = ± ia. Since there are a finite number of singular points, the function is meromorphic.
Summary In this chapter we investigated complex sequences and series. A sequence of complex numbers is a function of the integers. The behavior of a sequence can be investigated in the limit of the argument as it tends to infinity. A sequence can describe an individual term in a series, which can be used to represent a complex function. The convergence of series can be investigated using various tests such as the ratio test. Of particular interest in the study of complex variables, is the Laurent series, and we classify functions of a complex variable by looking at singularities which occur in the series expansion.
Quiz 2z 1. Does the sequence 1 + converge? If so find an N so that you can define n its limit. n
2. Find
∑ cos kθ . k =0
3. Find the radius of convergence for the Maclaurin expansion of z cot z. ∞
4. Find the radius of convergence for ∑ (3 + (−1)n )n z n . n =1 1 ⎫ convergent? If so over what values of z? 5. Is the sequence ⎧⎨ ⎬ ⎩1 + nz ⎭
CHAPTER 5
Sequences and Series
6. Find the Maclaurin expansion of f ( z ) = ∞
7. Describe the convergence of
115
z . z4 + 9
zn
∑ n(n + 1). n =1
8. Find the Taylor series expansion of sinh z about the point z0 = π i. ∞
2 1 2π f (reiθ ) dθ = ∫ 0 2π n= 0 ∞ 1 2π r cosθ 2 e dθ . an r 2 n. Use it to find a series representation for ∑ 2π ∫0 n= 0 1 1 + for 1 < z < 2 . 10. Find the Laurent series expansion of f ( z ) = z − 1 ( z − 2)2 z − sin z in a Laurent series and describe the singularity 11. Expand f ( z ) = z2 at z = 0.
9. Parseval’s theorem tells us that if f ( z ) = ∑ an z n then
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CHAPTER 6
Complex Integration
The study of elementary calculus involves differentiation and integration. We studied differentiation of complex functions in Chap. 3, now we turn to the problem of integration. It turns out that integration of complex functions is a very elegant procedure. The techniques developed here can not only be used to integrate complex functions but they can also be used as a toolbox to evaluate many integrals of real functions. We start the chapter with a simple evaluation of complex functions that are parameterized by a real parameter t and then introduce contour integration. Complex integration involves integration along a curve.
Complex Functions w(t) Suppose that a complex-valued function w = f (z) is defined in terms of one real variable t as follows: w(t ) = u(t ) + iv (t ) and that we are considering an interval a ≤ t ≤ b.
Copyright © 2008 by The McGraw-Hill Companies, Inc. Click here for terms of use.
(6.1)
Complex Variables Demystified
118
Now, the definite integral of w = f ( z ) can be written as
∫
b a
b
b
a
a
w(t ) dt = ∫ u(t ) dt + i ∫ v (t ) dt
The integral of the complex function w = f ( z ) has been translated into two integrals of the real functions u(t ) and v (t ). We can integrate these functions using the fundamental theorem of calculus provided that certain conditions are met. Make the definitions: dU = u(t ) dt
dV = v (t ) dt
and
Then it follows that
∫
b
b
b
a
a
w(t ) dt = ∫ u(t ) dt + i ∫ v (t ) dt
a
= U (b) − U (a) + i [V (b) − V (a)] EXAMPLE 6.1 Compute the integral
∫
2 0
(1 − it )2 dt.
SOLUTION The first step is to write the integrand in terms of real and imaginary parts. In this case (1 − it )2 = (1 − it )(1 − it ) = 1 − i 2t − t 2 = 1 − t 2 − i 2t This leads us to make the following definitions: u(t ) = 1 − t 2
v (t ) = −2t
and
The integral can then be written as
∫
2 0
2
2
(1 − it )2 dt = ∫ u(t ) dt + ∫ v (t ) dt 0
2
0
2
= ∫ (1 − t ) dt − i ∫ 2t dt 0
2
0
CHAPTER 6
Complex Integration
119
These are elementary integrals that are easy to evaluate:
∫
2 0
2
(1 − t 2 ) dt − i ∫ 2t dt = t − 0
2 t3 8 2 − it 2 = 2 − − 4i = − − 4i 3 3 3 0
EXAMPLE 6.2 Evaluate
∫
π /5 0
ei 2 t dt.
SOLUTION Using tools from elementary calculus we have
∫
π /4 0
ei 2 t dt =
π /4 i i i 1 i 2t π / 4 e = − ei 2 t = − eiπ / 2 + 2i 2 2 2 0 0
Now use Euler’s formula: eiπ / 2 = cos(π / 2) + i sin(π / 2) = i And so the integral evaluates to
∫
π /4 0
i i 1+ i ei 2 t dt = − (i ) + = 2 2 2
Properties of Complex Integrals If f ( z ) is a function that depends on one real variable t such that f = u(t ) + iv (t ) then we can use theorems from the calculus of real variables to handle more complex integrals. Suppose that α = c + id is a complex constant. You will recall from the calculus of real variables that we can pull a constant outside of an integral. The same holds true here, where we have
∫
b a
b
b
b
a
a
a
α f dt = ∫ (c + id )(u + iv ) dt = (c + id ) ∫ u dt + i (c + id ) ∫ v dt
(6.2)
Let g be another complex function depending on a single real variable such that g(t ) = r (t ) + is(t ). The integral of the sum or difference f ± g is
∫
b a
b
b
a
a
( f ± g) dt = ∫ f dt ± ∫ g dt
(6.3)
Complex Variables Demystified
120
Of course, we can also add the real and imaginary parts of the two functions:
∫
b a
b
b
b
a
a
a
( f ± g) dt = ∫ (u + iv ) ± (r + is) dt = ∫ (u ± r ) dt + i ∫ ( v ± s) dt
The product of two complex functions of a single real variable can be integrated as follows:
∫
b a
b
b
b
a
a
a
( fg) dt = ∫ (u + iv )(r + is) dt = ∫ (ur − vs) dt + i ∫ ( vr + us) dt
(6.4)
As in the calculus of real variables, we can split up an interval a ≤ t ≤ b. Suppose that a < c < b . Then we can write
∫
b a
c
b
a
c
f (t ) dt = ∫ f (t )dt + ∫ f (t ) dt
(6.5)
Exchanging the limits of integration introduces a minus sign:
∫
b a
a
f (t ) dt = − ∫ f (t )dt
(6.6)
b
The next example is somewhat contrived, since we could calculate the desired result easily, but it illustrates how the formulas could be applied and gives us practice calculating an integral of a complex function. EXAMPLE 6.3 π /2
π /2
π /4
Given that ∫ 0 e t +it dt = eπ / 2 /2 − [(1 − i ) / 2], find ∫ π / 4 e t +it dt by calculating ∫ 0 e t +it dt . SOLUTION The integral is easy to calculate. We have
∫
π /4 0
e t +it dt = ∫
π /4 0
e(1+i )t dt =
1 (1+i )t π / 4 1 (1+i )π / 4 e = (e − 1) 0 1+ i 1+ i
Euler’s formula tells us that e(1+i )π / 4 = eπ / 4 eiπ / 4 = eπ / 4 (cos(π / 4) + i sin(π / 4))) A table of trigonometric functions can be consulted to learn that cos(π / 4) = sin(π / 4) =
2 1 = 2 2
CHAPTER 6
Complex Integration
And so e(1+i )π / 4 =
121
eπ / 4 (1 + i ) 2
Hence the integral is
∫
π /4 0
e t +it dt =
1 1 ⎛ eπ / 4 ⎞ eπ / 4 1 1 (e(1+i )π / 4 − 1) = ( + i ) − 1 = − ⎜ ⎟ ⎠ 1+ i 1+ i ⎝ 2 2 1+ i
Writing the last term in standard form we obtain 1 1 ⎛1− i⎞ 1− i = = 1 + i 1 + i ⎜⎝ 1 − i ⎟⎠ 2 Therefore:
∫
π /4
e t +it dt =
0
eπ / 4 2
−
1− i 2
Now we use to write an expression that can be used to find the desired integral:
∫ ⇒∫
π /2 0
π /2
π /4
e t +it dt = ∫ e t +it dt = ∫
π /4 0
π /2 0
e t +it dt + ∫
π /2
e t +it dt − ∫
π /4
π /4
0
e t +it dt e t +it dt
=
eπ / 2 ⎛ 1 − i ⎞ ⎛ eπ / 4 1 − i ⎞ eπ / 2 ⎛ 1 − i ⎞ eπ / 4 ⎛ 1 − i ⎞ +⎜ −⎜ − = −⎜ ⎟− ⎟ ⎟− 2 ⎝ 2 ⎠ ⎜⎝ 2 2 ⎟⎠ 2 ⎝ 2 ⎠ 2 ⎝ 2 ⎠
=
eπ / 2 eπ / 4 − 2 2
Contours in the Complex Plane So far, we’ve seen how to evaluate integrals of simple functions of a complex variable—that were defined in terms of a single real parameter we called t. Now it’s time to generalize and consider a more general case, where we just say we’re integrating a function of a complex variable f ( z ), where z ∈. This can be done using a technique called contour integration. The reason integrals of complex functions are done the way they are is that while an integral of a real-valued function is defined on an interval of the line, an integral
122
Complex Variables Demystified
Figure 6.1 A curve γ (t ) is said to be simple if it does not cross itself.
of a complex-valued function is defined on a curve in the complex plane. We say that a set of points in the complex plane z = ( x , y) is an arc if x = x (t ) and y = y(t ) are continuous functions of a real parameter t which ranges over some interval (i.e., a ≤ t ≤ b). A complex number z can be written as z (t ) = x (t ) + iy(t ) Define a curve as a continuous function γ (t ) that maps a closed interval a ≤ t ≤ b to the complex plane. If the curve γ (t ) that defines a given arc does not cross itself, which means that γ (t1 ) ≠ γ (t2 ) when t1 ≠ t2 , then we say that γ (t ) is a simple curve or Jordan arc. A simple curve is illustrated in Fig. 6.1. If the curve crosses over itself at any point, then it is not simple. An example of this is shown in Fig. 6.2. The curves in Figs. 6.1 and 6.2 are open. If γ (a) = γ (b), that is γ (t ) assumes the same value at the endpoints of the interval a ≤ t ≤ b, but at no other points, then we say that γ (t ) is a simple closed curve or closed contour. This is shown in Fig. 6.3. Formally, we say that a curve γ (t ) is a simple closed curve if γ (a) = γ (b) and γ (t ) is one-to-one.
Figure 6.2 A curve which crosses itself at one or more points is not simple.
CHAPTER 6
Complex Integration
123
Figure 6.3 A simple, closed curve.
When using contour integration, the sense or direction in which the curve is traversed is important. To understand this, we consider a simple example, the unit circle centered about the origin. For example, consider z = eiθ where 0 ≤ θ ≤ 2π . If you put in some values as q ranges over the given interval increasing from 0, you will note that the points sweep out the circle in the counterclockwise direction. To see this, write the points in the complex plane as z = ( x , y). Let’s plug in a few points:
θ = 0 ⇒ z = ei 0 = cos 0 + i sin 0 = (1, 0) ⎛ 1 1 ⎞ θ = π / 4 ⇒ z = eiπ / 4 = cos(π / 4) + i sin(π / 4) = ⎜ , ⎝ 2 2 ⎟⎠
θ = π / 2 ⇒ z = eiπ / 2 = cos(π / 2) + i sin(π / 2) = (0,1) θ = π ⇒ z = eiπ = cos π + i sin π = (−1, 0) Following the curve in the counter-clockwise direction can be said to be in the positive sense since it moves with increasing angle. When drawing a contour, we use an arrow to indicate the directional sense we are using to move around it. This is illustrated in Fig. 6.4. If we move around the curve in the opposite direction, which is clockwise, we’ll call that negative because we will be moving opposite to the direction of increasing angles. Now consider the function: z = e − iθ
Complex Variables Demystified
124 y
x
Figure 6.4 A closed contour traversed in the positive sense, which is counter-clockwise. We say that this is in the positive sense because the curve is traversed in the direction of increasing angle q in the complex plane.
This also describes the unit circle, but we are traversing the circle in the counterclockwise direction. Notice that
θ = 0 ⇒ z = e − i 0 = cos 0 − i sin 0 = (1, 0) 1 ⎞ ⎛ 1 θ = π / 4 ⇒ z = e − iπ / 4 = cos(π / 4) − i sin(π / 4) = ⎜ ,− ⎟ ⎝ 2 2⎠
θ = π / 2 ⇒ z = e − iπ / 2 = cos(π / 2) − i sin(π / 2) = (0, −1) θ = π ⇒ z = e − iπ = cos π − i sin π = (−1, 0) The case of traversing a circle in the clockwise or negative direction is illustrated in Fig. 6.5.
Complex Line Integrals In this section, we will formalize what we’ve done so far with integration a bit. First let’s review important properties a function must have so that we can integrate it. DEFINITION: CONTINUOUSLY DIFFERENTIABLE FUNCTION Let a function f (t ) map the interval a ≤ t ≤ b to the real numbers. Formally, we write f : [a, b] → . We say that f (t ) is continuously differentiable over this interval, 1 which we indicate by writing f ∈C ([a, b]) if the following conditions are met: • The derivative df/dt exists on the open interval a < t < b. • The derivative df/dt has a continuous extension to a ≤ t ≤ b.
CHAPTER 6
Complex Integration
125
y
x
Figure 6.5 Traversing the contour in the negative or clockwise direction.
This allows us to utilize the fundamental theorem of calculus. This tells us that
∫
b a
f (t ) dt = f (b) − f (a)
(6.7)
Now we will extend this to curves in the complex plane. Suppose that a curve γ (t ) = f (t ) + ig(t ). DEFINITION: CONTINUOUSLY DIFFERENTIABLE CURVE Let γ (t ) be a curve, which maps the closed interval a ≤ t ≤ b to the complex plane. We say that γ (t ) is continuous on a ≤ t ≤ b if f (t ) and g(t ) are both continuous on a ≤ t ≤ b. If f (t ) and g(t ) are both continuously differentiable functions on a ≤ t ≤ b, then the curve γ (t ) is continuously differentiable. This is indicated by writing γ ∈C 1 ([a, b]). If γ (t ) is continuously differentiable and γ (t ) = f (t ) + ig(t ), then the derivative is given by dg dγ df = +i dt dt dt
(6.8)
We’ve already seen that we can write the integral of w(t ) = u(t ) + iv (t ) as ∫ ba u(t )dt + i ∫ ba v (t )dt. If the curve γ (t ) = f (t ) + ig(t ) is continuously differentiable, then we can write what might be called the fundamental theorem of calculus for curves in the complex plane:
∫
b a
γ ′(t ) dt = γ (b) − γ (a)
(6.9)
Complex Variables Demystified
126
This result can be extended further. We consider a domain D in the complex plane and a curve γ (t ) which maps a real, closed interval a ≤ t ≤ b into D. If there is a continuously differentiable function h, which maps D into the real numbers, then the integral along the curve is given by
∫
⎛ ∂h df ∂h dg ⎞ γ (t ) + γ (t ) ⎟ dt = h(γ (b))) − h(γ (a)) a ⎜ ⎝ ∂x dt ∂y dt ⎠ b
(6.10)
DEFINITION: COMPLEX LINE INTEGRAL OR CONTOUR INTEGRAL Now suppose that the curve γ (t ) is a simple closed curve. Then the complex line integral of a function F ( z ) of a complex variable is written as
∫ F (z ) dz = ∫
b a
F (γ (t ))
dγ dt dt
(6.11)
The integral in Eq. (6.11) is known as a contour integral. EXAMPLE 6.4 Suppose that 0 ≤ t ≤ 1, f ( z ) = z and we integrate along the curve γ (t ) = 1 + (i − 1)t. Calculate ∫ f ( z )dz . SOLUTION This can be done by using Eq. (6.11). Given that γ (t ) = 1 + (i − 1)t , we see that dγ = i −1 dt We also have that f ( z ) = f (γ (t )) = z = 1 + (i − 1)t and so
∫
b a
F (γ (t ))
1 dγ dt = ∫ (1 + (i − 1)t )(i − 1) dt 0 dt 1
= (i − 1) ∫ (1 + (i − 1)t ) dt 0
⎛ t2 ⎞ 1 = (i − 1) ⎜ t + (i − 1) ⎟ 2⎠ 0 ⎝ ⎛ i + 1⎞ = (i − 1) ⎜ = −1 ⎝ 2 ⎟⎠
CHAPTER 6
Complex Integration
127
EXAMPLE 6.5 Suppose that f ( z ) = z 2 + 1. Integrate f ( z ) around the unit circle. SOLUTION We can integrate around the unit circle by defining the curve:
γ (t ) = eit The interval mapped by this curve to the complex plane is 0 ≤ t ≤ 2π . We find that the derivative of the curve is dγ d = (eit ) = ieit dt dt Using Eq. (6.11) we have
∫ f (z ) dz = ∫
b
f (γ (t ))
a
2π dγ dγ dt = ∫ (γ 2 + 1) dt 0 dt dt
2π
= ∫ ((eit )2 + 1)(ieit ) dt 0
2π
= i ∫ (ei 3 t + eit ) dt 0
2π 1 = ei 3 t + eit 3 0 1 = (ei 6π − 1) + (ei 2π − 1) = 0 3 This result follows since for any even m, eimπ = cos(mπ ) + i sin(mπ ) = 1 + i 0 = 1.
The Cauchy-Goursat Theorem Now let’s take a turn that we’re going to use to develop the groundwork for residue theory, the topic of the next chapter. First let’s begin by looking at complex integration once again. We’ll dispense with the parameter t and instead focus on functions of x and y. So we have w = f ( z ) = u( x , y) + iv ( x , y)
Complex Variables Demystified
128 With z = x + iy , then
dz = dx + idy
(6.12)
So we can write the integral of a complex function along a curve γ in the following way:
∫ f (z ) dz = ∫ (u + iv)(dx + idy) = ∫ udx − vdy + i ∫ vdx + udy γ
γ
γ
(6.13)
γ
With this in hand, we can define the fundamental theorem of calculus for a function of a complex variable as follows. Suppose that f ( z ) has an antiderivative. That is: f (z) =
dF dz
The fundamental theorem of calculus then becomes dF
b
∫ f (z ) dz = ∫ dz dz = F (z ) a = F (b) − F (a) γ
(6.14)
γ
To prove this result, we use F ( z ) = U + iV . We are assuming that f and F are analytic. Now, using the results of Chap. 3 we know that f (z) =
∂U dF ∂U ∂V ∂V −i = = +i ∂y dz ∂x ∂x ∂y
and so dF
∫ f (z )dz = ∫ dz dz γ
γ
=∫ γ
⎛ ∂V ∂V ⎞ ∂U ∂U dy⎟ dx + dy + i ⎜ ∫ dx + ∂y ⎠ ∂x ∂y ⎝ γ ∂x
But since U = U ( x , y) using the chain rule we know that dU =
∂U ∂U dx + dy ∂y ∂x
CHAPTER 6
Complex Integration
129
and similarly for dV. Hence dF
∫ f ( z ) dz = ∫ dz dz γ
γ
= ∫ dU + i ∫ dV γ
γ
=U
z=b b + iV z=a a
= F (b) − F (a) The fundamental theorem of calculus allows us to evaluate many integrals in the usual way. EXAMPLE 6.6 n Find ∫γ f ( z )dz when f ( z ) = z for the case of z (= a) ≠ z (= b), and when the curve is closed, that is when a = b.
SOLUTION The fundamental theorem allows us to evaluate the integral in the same way we would in the calculus of real variables. We have n ∫ z dz =
γ
z n+1 z = b n +1 z = a
When z (= a) ≠ z (= b) this is just 1 (b n+1 − a n+1 ) n +1 If the curve is closed, then a = b and we have the result:
∫ z dz = 0 n
γ
This result holds provided that n ≠ −1. The case when n = −1 introduces us to an interesting phenomena or feature of complex integration. This is the fact that the contour we select for our integration will determine what the result is. First let’s do the integral
∫ γ
dz z
Complex Variables Demystified
130
using Eq. (6.11), choosing the unit circle as our contour and letting 0 ≤ t ≤ 2π . So, γ (t ) = eit. Then we have
∫ γ
2π 1 d dz =∫ (eit )dt 0 e it dt z 2π
= ∫ e − it (ieit ) dt 0
2π
= i ∫ dt = 2π i 0
Let’s look at the integration another way. Now, the domain of f ( z ) = 1 / z is the complex plane less the origin. We write this formally as \ {0}. The antiderivative of f ( z ) is F ( z ) = ln z = ln r + iθ . The domain of the antiderivative is \ (−∞,0]. We can do the integral avoiding \ (−∞,0] by taking the contour shown in Fig. 6.6 (notice it is not a closed contour). To do the integral with this contour, we choose a = re − iπ , b = reiπ Note that ln(b) = ln(reiπ ) = ln r + iπ ln(a) = ln(re − iπ ) = ln r − iπ Using the fundamental theorem of calculus, the integral is
∫ γ
b dz = ln( z ) = ln(b) − ln( z ) = ln r + iπ − (ln r − iπ ) = i 2π z a
b •
z=0
a
Figure 6.6 A contour that has the point z = 0, a singularity of f ( z ) = 1 / z , inside the path.
CHAPTER 6
Complex Integration
131
a=b z=0
•
Figure 6.7 We pick a contour that avoids the singularity all together.
This is the same result we obtained using the unit circle and Eq. (6.11). In both cases, the singularity of f ( z ) , the point z = 0 was included inside the path. What if we take a closed contour that does not include z = 0? Such a contour is shown in Fig. 6.7. This time we have a = b and so
∫
dz =0 z
This result suggests the theorem of Cauchy. THEOREM 6.1: CAUCHY’S INTEGRAL THEOREM Let U be a simply connected domain and define a function f : U → . The Cauchy’s integral theorem tells us that if w = f ( z ) is analytic on a simple, closed curve γ and in its interior, then
∫ f (z ) dz = 0
(6.15)
γ
Note that, we take the integration along the curve to be in the positive sense. We can indicate this explicitly by writing
∫
γ
f ( z )dz
To prove the theorem, we write
∫ f (z) dz = ∫ (u + iv)(dx + idy) = ∫ udx − vdy + i ∫ vdx + udy γ
γ
γ
γ
We can rewrite this result in terms of partial derivatives and then use Cauchy-Riemann to prove the theorem (we can do this because the assumption of the theorem is that the function is analytic). First we call upon Green’s theorem which states that ⎛ ∂Q
∂P ⎞
∫ Pdx + Qdy = ∫ ∫ ⎜⎝ ∂x − ∂y ⎟⎠ dxdy γ
R
Complex Variables Demystified
132
where R is a closed region in the plane. Now recall that the Cauchy-Riemann equations tell us ∂v ∂u =− ∂x ∂y Green’s theorem together with this result gives ∂u
∂v
∂v
∂v
∫ udx − vdy = ∫∫ − ∂y − ∂x dxdy = ∫∫ ∂x − ∂x dxdy = 0 γ
Similarly, we have i ∫ vdx + udy = i ∫∫ γ
∂u ∂v − dxdy ∂x ∂y
But the other Cauchy-Riemann equation states that ∂u ∂v = ∂x ∂y So the second term vanishes as well. This proves the theorem. The fundamental theorem of calculus in Eq. (6.14) is actually a consequence of Cauchy’s integral theorem. The converse, if you will, of Cauchy’s integral theorem is called Morera’s theorem. THEOREM 6.2: MORERA’S THEOREM Let f ( z ) be a continuous, complex-valued function on an open set D in the complex plane. Suppose that
∫ f (z ) dz = 0 γ
for all closed curves g. Then it follows that f ( z ) is analytic. Next, we extend Cauchy’s integral theorem to include singularities in the integrand. THEOREM 6.3: THE CAUCHY’S INTEGRAL FORMULA Let f ( z ) be analytic on a simple closed contour γ and suppose that f ( z ) is also analytic everywhere on its interior. If the point z0 is enclosed by g, then f (z)
∫ z − z γ
0
dz = 2π i f ( z0 )
(6.16)
CHAPTER 6
Complex Integration
133
EXAMPLE 6.7 Let γ be the unit circle traversed in a positive sense and suppose that f (z) = Find
z 4 − z2
∫ [ f (z ) / {z − (i / 2)}]dz . γ
SOLUTION We can apply the Cauchy’s integral formula since z0 = i / 2 is inside the circle and f ( z ) is analytic in the given domain (the function has a singularity at z = ±2, but these points are outside the unit circle). Hence ⎛ 4π i/2 ⎞ f (z) ⎟ =− ⎜ dz = i ⋅ f ( i ) = i π π 2 / 2 2 ∫γ z − i / 2 2 17 ⎜⎝ 4 − ( i / 2 ⎟⎠
)
EXAMPLE 6.8 Let f ( z ) = 5z − 2 and γ be the circle defined by |z| = 2. Compute
∫
γ
5z − 2 dz z −1
SOLUTION The function f ( z ) = 5z − 2 is clearly analytic on and inside the curve. Also, the point z = 1 lies inside |z| = 2. So, we can use Eq. (6.16) to evaluate the integral. We have
∫
γ
5z − 2 dz = 2π i f ( z0 ) = 2π i (5 − 2) = 6π i z −1
Summary In this chapter, complex integration was first considered along a curve parameterized with a single real parameter. Integration in this case is straight forward. We then built up to the Cauchy’s integral formula, by developing the fundamental theorem of calculus for a function of a complex variable and then stating and proving Cauchy’s integral theorem. In the next chapter, we introduce the elegant theory of residues which is an extension of Cauchy’s integral formula.
134
Complex Variables Demystified
Quiz 1. Evaluate ∫ 10 (t − i )3 dt. 2. Compute ∫ π0 /6 ei 2 t dt . 3. Calculate ∫ π0 / 2 e t +it dt . 4. Find ∫ π0 e t sin t dt using ∫ π0 e t +it dt . 5. Suppose that m and n are integers such that m ≠ n . Find ∫ 20π ei ( m−n )θ dθ. 6. Integrate f ( z ) = z 2 around the unit circle which is defined by γ (t ) = cos t + i sin t and t ∈[0, 2π ) . x ds 7. Use complex integration to find ∫ . 0 1 + s2 zdz 8. Consider a positively oriented circle with |z| = 2. Evaluate ∫ (4 − z 2 )(z + i) . zdz 9. Let γ be the positively oriented unit circle and f ( z ) = z . Evaluate ∫ 2z + 1. 10. Let γ be a positively oriented curve defined by a square with sides located sin z dz . at x = ± 3 and y = ± 3. Evaluate ∫ ⎛ π⎞ 2 z+ ( z + 16) ⎝ 2⎠
CHAPTER 7
Residue Theory
In the last chapter, we introduced the notion of complex integration. An important part of our development was the statement of Cauchy’s integral formula. In this chapter, we’re going to extend this technique using residue theory. This is an elegant formulation that not only allows you to calculate many complex integrals, but also gives you a trick you can use to calculate many real integrals. We begin by stating some theorems related to Cauchy’s integral formula.
Theorems Related to Cauchy’s Integral Formula We begin the chapter by writing down another form of Cauchy’s integral formula. First let’s write Eq. (6.16) in the following way: f (a) =
1 f ( z) dz ∫ 2π i γ z − a
Copyright © 2008 by The McGraw-Hill Companies, Inc. Click here for terms of use.
(7.1)
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136
Now let’s take the derivative of this expression, with respect to a. This gives f ′(a) =
d ⎡ 1 f ( z) ⎤ 1 d ⎡ f ( z) ⎤ 1 f ( z) dz ⎥ = dz = dz ⎢ ∫ ∫ ∫ ⎢ ⎥ da ⎢⎣ 2π i γ z − a ⎥⎦ 2π i γ da ⎣ z − a ⎦ 2π i γ ( z − a)2
We can repeat this process multiple times. That is, take the derivative again. Each time the exponent, which is negative, cancels out the minus sign we pick up by computing the derivative with respect to a of z − a. For example, the second derivative is f ′′(a) =
⎞ 1 d ⎛ 1 f ( z) f ( z) dz dz ⎜ ⎟= 2 3 ∫ ∫ da ⎝ 2π i γ ( z − a) ⎠ π i γ ( z − a)
This process can be continued. For an arbitrary n, we obtain a second Cauchy’s integral formula for the nth derivative of f (a): f ( n ) (a) =
n! f ( z) ∫γ (z − a)n+1 dz 2π i
for n = 1, 2, 3,...
(7.2)
There are two facts you should come away with from Cauchy’s integral formulas: • If a function f (z) is known on a simple closed curve g, then that function is known at all points inside g. Moreover, all of the functions derivatives can be found inside g. • If a function is analytic in a simply connected region of the complex plane, and hence has a first derivative, all of its higher derivatives exist in that simply connected region. Now we turn to a statement known as Cauchy’s inequality. This statement is related to Eq. (7.2), which gives us an expression we can use to calculate the derivative of an analytic function in a simply connected region. Consider a circle of radius r, which has the point z = a at its center, and suppose that f (z) is analytic on the circle and inside the circle. Let M be a positive constant such that | f ( z) | ≤ M in the region | z − a | < r . Then f ( n ) (a) ≤
Mn ! rn
(7.3)
The next theorem, which is due to Liouville, tells us that an entire function cannot be bounded unless it is a constant. This statement is called Liouville’s theorem but it was first proved by Cauchy. So maybe we should call it the Cauchy-Liouville theorem. In any case, it simply says that if f (z) is analytic and bounded in the entire complex plane, that is, f ( z) < M for some constant M, then f (z) is a constant.
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Liouville’s theorem implies the fundamental theorem of algebra. Consider a polynomial with degree n ≥ 1 and coefficient an ≠ 0: P ( z) = a0 + a1z + a2 z 2 + + an z n The fundamental theorem of algebra tells us that every polynomial P ( z) has at least one root. The proof follows from Liouville’s theorem and the use of a proof by contradiction. Suppose that instead P ( z) ≠ 0 for all z. Then f ( z) =
1 P( z)
is analytic throughout the complex plane and is bounded outside some circle z = r . Moreover, the assumption that P ( z) ≠ 0 implies that f = 1/P is also bounded for z ≤ r . Hence 1/P ( z) is bounded in the entire complex plane. Using Liouville’s theorem, 1/P ( z) must be a constant. This is a contradiction, since P(z) = a0 + a1z + a2 z 2 + + an z n is clearly not constant. Therefore P ( z) must have at least one root such that P ( z) = a0 + a1z + a2 z 2 + + an z n = 0 is satisfied. Next we state the maximum modulus theorem and the minimum modulus theorem. The maximum modulus theorem tells us the following. Let f (z) be a complexvalued function which is analytic inside and on a simple closed curve g. If f (z) is not a constant, then the maximum value of f ( z) is found on the curve g. Now we state the minimum modulus theorem. Assume once again that f (z) is a complex-valued function which is analytic inside and on a simple closed curve g. If f ( z) ≠ 0 inside g, then f ( z) assumes its minimum value on the curve g. The next theorem is the deformation of path theorem. Consider a domain D in the complex plane, and two curves in D we call γ 1 and γ 2. We suppose that γ 1 is larger than or lies outside of γ 2 , and that γ 1 can be deformed into γ 2 without leaving the domain D [that is, we can shrink the first curve down to the second one without crossing any holes or discontinuities in the domain (Fig. 7.1)]. If f (z) is analytic in D then
∫
γ1
f ( z) dz = ∫ f (z) dz γ2
(7.4)
Next, we state Gauss’ mean value theorem. Consider a circle g of radius r centered at the point a. Let f (z) be a function, which is analytic on and inside g. The mean value of f (z) on g is given by f (a): f (a) =
1 2π
∫
2π 0
f (a + reiθ ) dθ
(7.5)
Complex Variables Demystified
138
g1 Can have hold inside second curve.
g2
If first curve has to cross hole to deform into second curve, theorem does not work.
Figure 7.1 A graphic illustration of the deformation of path theorem.
Once again, let f (z) be a function, which is analytic on and inside a simple, closed curve g. Now assume that f (z) has a finite number of poles inside g. If M is the number of zeros of f (z) inside g and N is the number of poles inside g, the argument theorem states that 1 f ′( z) dz = M − N ∫ 2π i γ f ( z)
(7.6)
Next is a statement of Rouche’s theorem. Let f (z) and g (z) be two functions, which are analytic inside and on a simple closed curve g. If g( z) ≤ f ( z) on γ , then f ( z) + g( z) and f ( z) have the same number of zeros inside g. Finally, we end our whirlwind tour of theorems and results related to the Cauchy’s integral formula with a statement of Poisson’s integral formula for a circle. This expresses the value of a harmonic function inside of a circle in terms of its values on the boundary. Let f (z) be analytic inside and on the circle g, centered at the origin with radius R. Suppose that z = reiθ is any point inside g. Then f ( z) =
1 2π
∫
2π 0
( R 2 − r 2 ) f (Reiφ ) dφ R 2 − 2 Rr cos(θ − φ ) + r 2
(7.7)
EXAMPLE 7.1 This example illustrates the solution of Laplace’s equation on a disk. First show that ∞
u (r ,θ ) = a0 + ∑ an r n cos nθ + bn r n sin nθ n =1
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139
is the solution of Laplace’s equation on the disc 0 ≤ r ≤ 1 with Dirichlet boundary conditions: 1 ∂ ⎛ ∂u ⎞ 1 ∂2u =0 ⎜r ⎟ + r ∂r ⎝ ∂r ⎠ r 2 ∂r 2
0 < r < 1, 0 ≤ θ ≤ 2π
u (1,θ ) = f (θ ), u (r ,θ ) bounded as r → 0 Show the coefficients in the series expansion are given by a0 =
1 2π
∫
2π 0
f (θ ) dθ
an =
1 π
∫
2π 0
f (θ ) cos nθ dθ
bn =
1 π
∫
2π 0
f (θ )sin nθ dθ
Use the result to deduce Poisson’s integral formula for a circle of radius one: u (r ,θ ) =
1 2π
∫
2π 0
1 − r2 f (φ ) dφ 1 − 2r cos(θ − φ ) + r 2
SOLUTION We try separation of variables. Let u (r ,θ ) = R(r )Θ(θ ). Then it follows that ∂u ∂R = Θ(θ ) ∂r ∂r
∂2u ∂2 R = Θ(θ ) ∂r 2 ∂r 2
∂2u ∂2Θ = R ( r ) ∂θ 2 ∂θ 2
The statement of the problem tells us that ∂ 2u 1 ∂u 1 ∂ 2u =0 + + ∂r 2 r ∂r r 2 ∂θ 2 Hence 0=
∂2Θ ∂2 R 1 ∂R 1 Θ ( ) Θ ( ) + R ( r ) + θ θ r ∂r r2 ∂θ 2 ∂r 2
We divide every term in this expression by u (r ,θ ) = R(r )Θ(θ ). This allows us to write r 2 ∂ 2 R r ∂R 1 ∂2Θ = − + Θ ∂θ 2 R ∂r 2 R ∂r
Complex Variables Demystified
140
The left-hand side and the right-hand side are functions of r only and θ only, respectively. Therefore they can be equal only if they are both equal to a constant. We call this constant n 2 . Then we have the equation in θ : −
1 d 2Θ = n2 Θ dθ 2
⇒
d 2Θ + n 2Θ = 0 dθ 2
Note that partial derivatives can be replaced by ordinary derivatives at this point, since each equation involves one variable only. This familiar differential equation has solution given by Θ(θ ) = an cos nθ + bn sin nθ Now, turning to the equation in r, we have r 2 d 2 R r dR + = n2 2 R dr R dr
⇒ r2
d2R dR +r − n2 R = 0 2 dr dr
You should also be familiar with this equation from the study of ordinary differential equations. It has solution R(r ) = cn r n + c− n r − n The total solution, by assumption is the product of both solutions, that is, u (r ,θ ) = R(r )Θ(θ ). So we have u (r ,θ ) = (cn r n + c− n r − n )(an cos nθ + bn sin nθ ) The condition that u (r ,θ ) is bounded as r → 0 imposes a requirement that the constant c− n = 0 since c− n → ∞ as r → 0 rn Therefore, we take u (r ,θ ) = (cn r n )(an cos nθ + bn sin nθ ). We can just absorb the constant cn into the other constants, and still designate them by the same letters. Then u (r ,θ ) = r n (an cos nθ + bn sin nθ )
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The most general solution is a superposition of such solutions which ranges over all possible values of n. Therefore we write ∞
∞
n=0
n =1
u (r ,θ ) = ∑ r n (an cos nθ + bn sin nθ ) = a0 + ∑ r n (an cos nθ + bn sin nθ ) To proceed, the following orthogonality integrals are useful:
∫ ∫
0
2π 0
∫
⎧ πδ mn sin mθ sin nθ dθ = ⎨ ⎩0
for n ≠ 0 for n = 0
(7.8)
⎧ πδ mn cos mθ cos nθ dθ = ⎨ ⎩ 2πδ mn
for n ≠ 0 for n = 0
(7.9)
2π
2π 0
sin mθ cos nθ dθ = 0
(7.10)
Here, δ mn = 1 for m = n, 0 which is the Kronecker delta function. Now we apply the boundary condition u (1,θ ) = f (θ ) for 0 ≤ θ ≤ 2π : ∞
f (θ ) = a0 + ∑ r n (an cos nθ + bn sin nθ )
(7.11)
n =1
Multiply through this expression by sin mθ and integrate. We obtain
∫
2π 0
2π
f (θ )sin mθ dθ = a0 ∫ sin mθ dθ 0
∞
+∑ n =1
∞
=∑ n =1
(∫
(∫
2π 0
2π 0
2π
an cos nθ sin mθ dθ + ∫ bn sin nθ sin mθ dθ 0
)
where Eqs. (7.8)–(7.10) were used. We conclude that bn =
∞
bn sin nθ sin mθ dθ = ∑ bnπδ mn = π bm
1 π
∫
2π 0
f (θ )sin nθ dθ
n =1
)
Complex Variables Demystified
142
Now we return to Eq. (7.11), and multiply by cos mθ and integrate. This time
∫
2π 0
2π
f (θ ) cos mθ dθ = a0 ∫ cos mθ dθ 0
∞
+∑ n =1
∞
=∑ n =1
(∫
(∫
2π 0
2π 0
2π
an cos nθ cos mθ dθ + ∫ bn sin nθ cos mθ dθ 0
)
)
∞
an sin nθ cos mθ dθ = ∑ anπδ mn = π am n =1
Hence am =
1 π
∫
2π 0
f (θ ) cos mθ dθ
To obtain the constant a0 , we integrate without first multiplying by any trig functions, that is:
∫
2π 0
2π
∞
f (θ ) dθ = a0 ∫ dθ + ∑ 0
n =1
(∫
2π 0
2π
an cos nθ dθ + ∫ bn sin nθ dθ 0
)
= a0 2π ⇒ a0 =
1 2π
∫
2π 0
f (θ ) dθ
This should be obvious since
∫ ∫
2π 0 2π 0
cos nθ dθ =
1 sin nθ n
2π
=0
0
1 sin nθ dθ = − cos nθ n
2π
=0
0
Now we are in a position to derive Poisson’s formula. We have u (r ,θ ) =
1 2π ∞
∫
2π 0
f (φ ) dφ
⎡1 +∑ r n ⎢ ⎣π n =1
(∫
2π 0
)
f (φ ) cos nφ dφ cos nθ +
1 π
(∫
2π 0
)
⎤ f (φ )sin nφ dφ sin nθ ⎥ ⎦
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We can move the summation inside the integrals: u (r ,θ ) =
1 2π
∫
+∫
2π
2π 0
f (φ )
0
=
1 2π
∫
=
1 2π
∫
f (φ ) dφ + ∫
2π 0 2π 0
2π 0
f (φ )
1⎛ ∞ n ⎞ r cos nθ cos nφ ⎟ dφ ∑ ⎜ ⎠ π ⎝ n =1
1⎛ ∞ n ⎞ r sin nθ sin nφ ⎟ dφ ∑ ⎜ ⎠ π ⎝ n =1
∞ ∞ ⎧ ⎫ dφ f (φ ) ⎨1 + 2∑ r n cos nθ cos nφ + 2∑ r n sin nθ sin nφ ⎬ ⎩ ⎭ n =1 n =1 ∞ ⎧ ⎫ dφ f (φ ) ⎨1 + 2∑ r n (cos nθ cos nφ + sin nθ sin nφ )⎬ ⎩ ⎭ n =1
Now recall that cos nθ cos nφ + sin nθ sin nφ = cos(n(θ − φ )) It’s also true that ∞
1 − 2∑ r n cos [ n(θ − φ ) ] = n =1
1 − r2 1 − 2r cos(θ − φ ) + r 2
(7.12)
So, we arrive at the Poisson formula for a disc of radius one: u (r ,θ ) =
1 2π
∫
2π 0
1 − r2 f (φ ) dφ 1 − 2r cos(θ − φ ) + r 2
This tells us that the value of a harmonic function at a point inside the circle is the average of the boundary values of the circle.
The Cauchy’s Integral Formula as a Sampling Function The Dirac delta function has two important properties. First if we integrate over the entire real line then the result is unity:
∫
∞
δ ( x ) dx = 1
−∞
Complex Variables Demystified
144
Second, it acts as a sampling function—that is, it picks out the value of a real function f (x) at a point:
∫
∞ −∞
f ( x ) δ ( x − a)dx = f (a)
In complex analysis, the function 1 / z plays an analogous role. It has a singularity at z = 0, and 1 dz ⎧ 0 =⎨ ∫ 2π i γ z ⎩1
if 0 is not in the interior of γ if 0 is in the interior of γ
It also acts as a sampling function for analytic functions f (z) in that f (a) =
1 f ( z)dz ∫ 2π i γ z − a
Some Properties of Analytic Functions Now we are going to lay some more groundwork before we state the residue theorem. In this section, we consider some properties of analytic functions.
AN ANALYTIC FUNCTION HAS A LOCAL POWER SERIES EXPANSION Suppose that a function f (z) is analytic inside a disc centered at a point a of radius r: z − a < r . Then f (z) has a power series expansion given by ∞
f ( z) = ∑ an ( z − a)n
(7.13)
n=0
The coefficients of the expansion can be calculated using the Cauchy’s integral formula in Eq. (7.2): an =
f ( n ) (a) n!
(7.14)
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145
INTEGRATION OF THE POWER SERIES EXPANSION GIVES ZERO Note the following result:
∫ ( z − a) γ
m
if m ≠ −1 ⎧0 dz = ⎨ ⎩ ln( z − a) if m = −1
Hence ∞
∫ f (z) dz = ∑ a ∫ (z − a) dz n
n
n=0
γ
γ
since n is never equal to −1.
A FUNCTION f(z) THAT IS ANALYTIC IN A PUNCTURED DISC HAS A LAURENT EXPANSION Consider the punctured disc of radius r centered at the point a. We denote this by writing 0 < z − a < r. If f (z) is analytic in this region, it is analytic inside the disc but not at the point a. In this case, the function has a Laurent expansion: f ( z) =
∞
∑ a ( z − a)
n
n
(7.15)
n =−∞
As stated in Chap. 5, we can classify the points at which the function blows up or goes to zero. A removable singularity is a point a at which the function appears to be undefined, but it can be shown by writing down the Laurent expansion that in fact the function is analytic at a. In this case the Laurent expansion in Eq. (7.15) assumes the form ∞
f ( z) = ∑ an ( z − a)n n=k
where k ≥ 0. Then it turns out the point z = a is a zero of order k. On the other hand, suppose that the series expansion retains terms with n < 0: f ( z) =
∞
∑ a ( z − a)
n
n
n =− k
Then we say that the point z = a is a pole of order k. Simply put, a pole is a point that behaves like the point z = 0 for g( z ) = 1 / 2 . That is, as z → a , then f ( z) → ∞
Complex Variables Demystified
146
|Γ(z)| 6 4 2
5
5 0 Im(z)
0
0 Re(z) –5–5
Figure 7.2 When the real part of z is negative, the modulus of the gamma function blows to infinity at several points. These points are the poles of the function.
. A function might have multiple poles. For example, in Fig. 7.2 we illustrate the poles of the modulus of the gamma function, Γ( z) , which are points where the function blows up. A Laurent series expansion of this type can be split into two parts: f ( z) =
∞
∑ a ( z − a) n
n
=
n =− k
−1
∞
∑ a ( z − a) + ∑ a ( z − a) n
n
n =− k
n
n
= F+G
n=0
The second series, which we have denoted by G, looks like a plain old Taylor expansion. The other series, which we have denoted by F, is called the principal part and it includes the singularities (the real ones—the poles) of the function. EXAMPLE 7.2 Is the point z = 0 a removable singularity of f ( z ) = (sin z )/z ? SOLUTION At first glance, the behavior of the function at z = 0 can’t really be determined. To see what’s going on we expand the sin function in Taylor: f ( z) =
sin z 1 ⎛ 1 1 = ⎜ z − z 3 + z 5 + ⎞⎟ ⎝ ⎠ z z 3! 5!
= 1−
1 2 1 4 z + z + 5! 3!
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147
From this expression, it’s easy to see that lim f ( z) = lim z→0
z→0
sin z 1 1 = lim 1 − z 2 + z 4 + = 1 z → 0 z 3! 5!
Therefore, the point z = 0 is a zero of order one. EXAMPLE 7.3 z Describe the nature of the singularities of f ( z ) = e /z . SOLUTION We follow the same procedure used in Example 7.2. First expand in Taylor: f (z) =
ez 1 ⎛ z2 z3 z z2 ⎞ 1 = ⎜ 1 + z + + + ⎟ = + 1 + + + ⎠ z z z⎝ 2! 3! 2 6
The principal part of this series expansion is given by 1/z. It follows that the point z = 0 is a pole of order one. EXAMPLE 7.4 Is the point z = 0 a removable singularity of f ( z ) = (sin z )/z 4? SOLUTION Contrast this solution with that found in Example 7.2. Expanding in Taylor we find
f ( z) = =
sin z 1 ⎛ 1 1 1 = 4 ⎜ z − z 3 + z 5 − z 7 − ⎞⎟ 4 ⎝ ⎠ z z 3! 5! 7! 1 1 1 1 − + z − z3 + 3 6 z 5! 7! z
This time, the singularity cannot be removed. So the point z = 0 is a pole. The principal part in this series expansion is 1 1 − z3 6z The leading power (most negative power) in the expansion gives the order of the pole. Hence z = 0 is a pole of order three.
Complex Variables Demystified
148
ESSENTIAL SINGULARITY Next we consider the essential singularity. In this case, the Laurent series expansion of the function includes a principal part that is nonterminating. That is, all terms out to minus infinity are included in the Laurent expansion with negative n, that is, there are no nonzero terms in the expansion for n < 0: f ( z) =
∞
∑ a ( z − a)
n
n
n =−∞
EXAMPLE 7.5 Describe the nature of the singularity at z = 0 for f ( z ) = e1/ z . SOLUTION This function is the classic example used to illustrate an essential singularity. We just write down the series expansion: 1
f ( z) = e z 2
3
4
5
1 1 ⎛ 1⎞ 1 ⎛ 1⎞ 1 ⎛ 1⎞ 1 ⎛ 1⎞ = 1+ + ⎜ ⎟ + ⎜ ⎟ + ⎜ ⎟ + ⎜ ⎟ + 6 ⎝ z⎠ 4! ⎝ z ⎠ 5! ⎝ z ⎠ z 2 ⎝ z⎠ 1 1 1 1 = 1 + z −1 + z −2 + z −3 + z −4 + z −5 + 2 6 4! 5! This series expansion has a nonterminating principal part. Therefore z = 0 is an essential singularity.
The Residue Theorem Now we’re in a position where we can describe one of the central results of complex analysis, the residue theorem. We consider a function f ( z ) in a region enclosed by a curve γ that includes isolated singularities at the points z1 , z2 ,..., zk . The function is analytic everywhere on the curve and inside it except at the singularities. This is illustrated in Fig. 7.3. We can use the deformation of path theorem to shrink the curve down. In fact, we can shrink it down into isolated curves enclosing each singularity. This is shown in Fig. 7.4.
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149
• zk
• z1
• z0
Figure 7.3 A function f ( z ) is analytic in a certain region enclosed by a curve, except at a set of isolated singularities.
After application of the deformation of path theorem, the integral is broken up into a sum of integrals about each singular point:
∫ γ
k
f ( z) dz = ∑ ∫ f ( z) dz j =1 γ j
This expression can be written in terms of the Laurent expansion. Note that there will be a series expansion (which is local) about each singular point:
∫
γj
f ( z) dz =
∫
∞
∞
∑ anj (z − z j )n dz = ∑ anj ∫ (z − z j )n dz = a−j1 2π i
γ j n =−∞
n =−∞
γj
j −1
We call the coefficient in the expansion a the residue. Summing over all of the integrals for each singular point, we get the residue theorem. This states that the integral is proportional to the sum of the residues:
∫ γ
k
f ( z) dz = 2π i ∑ residues
(7.16)
j =1
• zk
• z0
gk
• z1 g2 g1
Figure 7.4 If the region is simply connected, we can apply the deformation of path theorem to shrink the curve down, until we have circles around each isolated singular point.
Complex Variables Demystified
150
Residues are computed by finding the limit of the function f ( z ) as z approaches each singularity. This is done for a singularity at z = a as follows: residue = lim z→a
1 d k −1 ⎡( z − a) k f ( z) ⎦⎤ ( k − 1)! dz k −1 ⎣
(7.17)
where k is the order of the singularity. EXAMPLE 7.6 Compute the integral 5z − 2
∫ z ( z − 2) dz γ
where g is a circle of radius r = 3 centered at the origin. SOLUTION The singularities of this function are readily identified to be located at z = 0, 2 . Both singularities are enclosed by the curve, since z < 3 in both cases. To find each residue, we compute the limit of the function for each singularity. The residue corresponding to z = 0 is lim z z→0
5z − 2 5z − 2 −2 = lim = =1 z → 0 z( z − 2) ( z − 2) −2
The residue corresponding to the singularity at z = 2 is lim( z − 2) z→2
5z − 2 5z − 2 8 = lim = =4 z( z − 2) z→2 z 2
Therefore using Eq. (7.16) the integral evaluates to 5z − 2
∫ z(z − 2) dz = 2π i∑ residues = 2π i(1 + 4) = 10π i γ
EXAMPLE 7.7 Compute the integral of ∫ γ [(cosh z ) /z 3 ]dz, where g is the unit circle centered about the origin. SOLUTION The function has a singularity at z = 0 of 3d order. Using f ( n ) (a) =
n! f ( z) dz ∫ 2π i γ ( z − a)n+1
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Residue Theory
151
We have cosh z 2π i d 2 dz (cosh z) = ∫ z3 2! dz 2
z=0
= π i(cosh z)
z=0
= πi
Evaluation of Real, Definite Integrals One of the most powerful applications of the residue theorem is in the evaluation of definite integrals of functions of a real variable. We start by considering
∫
2π 0
f ( cos θ ,sin θ ) dθ
Now, write the complex variable z in polar form on the unit circle, that is, let z = eiθ . Notice that dz = ieiθ dθ
⇒ dθ =
i 1 dz = − dz z iz
As θ increases from 0 to 2π , one sees that the complex variable z moves around the unit circle in a counter clockwise direction. Using Euler’s formula, we can also rewrite cos θ and sin θ in terms of complex variables. In the first case: cos θ =
eiθ + e − iθ ⎛ ei 2θ + 1 ⎞ ei 2θ + 1 z 2 + 1 = e − iθ ⎜ = = ⎝ 2 ⎟⎠ 2z 2 2eiθ
Similarly, we find that sin θ =
z2 − 1 2iz
Taking these facts together, we see that ∫ 20π f (cos θ ,sin θ ) dθ can be rewritten as a contour integral in the complex plane. We only need to include residues that are inside the unit circle. EXAMPLE 7.8 Compute ∫ 20π [dθ /(24 − 8 cosθ )].
Complex Variables Demystified
152
SOLUTION Using dθ = −(i / z )dz together with cosθ = ( z 2 + 1) / 2 z we have
∫
2π 0
dθ dz = −i ∫ 24 − 8 cos θ ⎡ ⎛ z 2 + 1⎞ ⎤ z ⎢ 24 − 8 ⎜ ⎝ 2 z ⎟⎠ ⎥⎦ ⎣ = −i ∫ = i ∫ =
dz 24 z − 4 z 2 − 4
dz 4 z − 24 z + 4 2
i dz 2 ∫ 4 z − 6z + 1
We will choose the unit circle for our contour. To find the singularities, we find the roots of the denominator. Some algebra shows that they are located at z = 3 ± 2 2. The first residue is given by lim
z→3+ 2 2
(z − 3 − 2 2 )
1
( z − 3 − 2 2 )( z − 3 + 2 2 )
=
1 4 2
The residue corresponding to z = 3 − 2 2 is given by lim
z →3 − 2 2
(z − 3 + 2 2 )
1
( z − 3 − 2 2 )( z − 3 + 2 2 )
=−
1 4 2
You should always check that your singularities lie inside the curve you are using to integrate. If they do not, they do not contribute to the integral. In this case, both residues do not contribute. This is because z = 3+ 2 2 >1 lies outside the unit circle. So we will only include the second residue, because the singularity it corresponds to, z = 3 − 2 2 < 1 and so is inside the unit circle. Using Eq. (7.16) we have
∫ z
2
1 ⎞ πi dz ⎛ = 2π i ∑ residues = 2π i ⎜ − ⎟⎠ = − ⎝ − 6z + 1 4 2 2 2
CHAPTER 7
Residue Theory
153
Hence
∫
2π 0
dθ i dz i ⎛ πi ⎞ π = = ⎜− = ⎟ 2 ∫ 24 − 8 cos θ 4 z − 6 z + 1 4 ⎝ 2 2 ⎠ 8 2
The next type of definite integral we consider is one of the form
∫
⎧ cos mx ⎫ f ( x) ⎨ ⎬ dx −∞ ⎩ sin mx ⎭ ∞
This type of integral can be converted into a contour integral of the form
∫ f (z) e
imz
(7.18)
dz
To obtain the desired result, we take the real or imaginary part of Eq. (7.18) depending on whether or not a cos or sin function is found in the original integral. A useful tool when evaluating integrals of the form in Eq. (7.18) is called Jordan’s lemma. Imagine that we choose γ to be a semicircle located at the origin and in the upper half plane, as illustrated in Fig. 7.5. Jordan’s lemma states that lim ∫ f ( z ) e mz dz = 0 R→∞
(7.19)
C1
Jordan’s lemma does not hold in all cases. To use Eq. (7.19), if m > 0 then it must be the case that f ( z) → 0 as R → ∞. We can also apply it in the following case: lim ∫ f ( z) dz = 0 R→∞
C1
provided that f ( z) → 0 faster than 1/z as R → ∞. y C1
C2 –R
0
x R
Figure 7.5 A semicircle in the upper half plane, of radius R.
Complex Variables Demystified
154 EXAMPLE 7.9 Compute ∫ ∞−∞[(cos kx )/ x 2 ]dx.
SOLUTION We can compute this integral by computing
∫
cos kx dx = Re I z −∞ x 2 ∞
where eikz I z = P ∫ 2 dz −∞ z ∞
The P stands for principal part. To do the integral, we will take a circular contour in the upper half plane which omits the origin. This is illustrated in Fig. 7.6. Now we can write out the integral piecewise, taking little chunks along the curves C1 and C2. Note that when directly on the real axis, we set z → x . This gives ikx ikx r e Re eikz eikz eikz dx dz dx dz = + + + ∫− R x 2 ∫ z2 ∫r x 2 C∫ z 2 dz = 0 ∫ z 2 C2 1
The entire sum of these integrals equals zero because the contour encloses no singular points. However, individual integrals in this expression are not all zero. By Jordan’s lemma: eikz ∫ z 2 dz = 0 C1 So, we only need to calculate the residues for the curve C2 . This curve is in the clockwise direction, so we need to add a minus sign when we do our calculation. y C1
x
C2 –R
–r 0
r
R
Figure 7.6 We use a semicircular contour in the upper half plane, omitting the origin using a small semicircle or radius r that gives us a curve that omits the origin.
CHAPTER 7
Residue Theory
155
Also, up to this point, we have been using full circles in our calculations. The curve in this case is a semicircle, so Eq. (7.16) is written as
∫ γ
k
f ( z) dz = −π i ∑ residues j =1
The singularity at z = 0 is inside the curve C2, of order two. The residue corresponding to this singularity is d ⎛ 2 eikz ⎞ z = ikeikz dz ⎜⎝ z 2 ⎟⎠ z =0
z=0
= ik
Therefore eikz ∫ z 2 dz = −iπ (ik ) = π k C2 Now
∫
ikx ikx r e Re eikz eikz = + + dz dx dx ∫− R x 2 ∫r x 2 C∫ z 2 dz = 0 z2 1
ikx ikx r e Re eikx = + dx dx ∫− R x 2 ∫r x 2 dx −∞ x 2 ikx ∞e eikz P ∫ 2 dx + ∫ 2 dz = 0 −∞ x z C1
P∫
∞
as r → 0
R → ∞⇒
Therefore we find that ikx ∞ e eikz cos kx dx dx I P = = = − Re z ∫−∞ x 2 ∫−∞ x 2 ∫ z 2 dz = −π k C1 ∞
Integral of a Rational Function The integral of a rational function f ( x )
∫
∞ −∞
f ( x ) dx
can be calculated by computing
∫ f ( z ) dz
Complex Variables Demystified
156
using the contour shown in Fig. 7.5, which consists of a line along the x axis from –R to R and a semicircle above the x axis the same radius. Then we take the limit R → ∞. EXAMPLE 7.10 Consider the Poisson kernel py ( x ) =
y 1 2 π x + y2
Treating y as a constant, use the residue theorem to show that its Fourier transform is given by [1 /(2π )]e − k y . SOLUTION The Fourier transform of a function f ( x ) is given by the integral F (k ) =
1 2π
∫
∞ −∞
f ( x ) e− ikx dx
(7.20)
So, we are being asked to evaluate the integral I=
1 2π
∫
∞ −∞
y 1 e − ikx dx 2 π x + y2
We do this by considering the contour integral 1
∫ 2π
2
y e − ikz dz 2 z +y 2
First, note that 1 y 1 y = 2 2 2 2 2π x + y 2π ( z + iy)( z − iy) Therefore, there are two simple poles located at z = ±iy . These lie directly on the y axis, one in the upper half plane and one in the lower half plane. To get the right answer for the integral we seek, we need to compute using both cases. First we consider the pole in the upper half plane. The residue corresponding to z = + iy is a−1 = ( z − iy)
ye − ikz 2π 2 ( z + iy)( z − iy)
z =+ iy
=
yeky 1 ky e = 2 2π (2iy) 4π 2i
CHAPTER 7
Residue Theory
157
Applying the residue theorem, we find that I=
1 2π
ky y 1 ⎛ 1 eky ⎞ = e − ikx e dx i π = 2 ⎜⎝ 2 ⎟ ∫−∞π x 2 + y2 4π i ⎠ 2π ∞
However, now let’s consider enclosing the other singularity, which would be an equally valid approach. The singularity is located at z = − iy, which is below the x axis, so we would need to use a semicircle in the lower half plane to enclose it. This time the residue is a−1 = ( z + iy)
ye − ikz 2π 2 ( z + iy)( z − iy)
z =− iy
=−
1 − ky e 4π 2i
Using this result, we obtain I=
1 2π
− ky y 1 ⎛ 1 e − ky ⎞ = e − ikx e dx i π = 2 ⎜ ⎟ ∫−∞π x 2 + y2 ⎝ 4π 2i ⎠ 2π ∞
Combining both results gives the correct answer, which is I=
e− k y 2π
EXAMPLE 7.11 Compute the integral given by I=∫
x2 dx −∞1 + x 4 ∞
SOLUTION This integral is given by I = 2π i ∑ residues in upper half plane We find the residues by considering the complex function f ( z) =
z2 z4 + 1
The singularities are found by solving the equation z4 + 1 = 0 This equation is solved by z = ( −1)1/ 4 . But, remember that −1 = eiπ .
Complex Variables Demystified
158
That is, there are four roots given by
z = e1/ 4(iπ )( 2 n+1)
⎧ eiπ / 4 ⎪ i 3π / 4 ⎪e = ⎨ i 5π / 4 ⎪e ⎪⎩ ei 7π / 4
These are shown in Fig. 7.7. Notice that two of the roots are in the upper half plane, while two of the roots are in the lower half plane. We reject the roots in the lower half plane because we are choosing a closed semicircle in the upper half plane (as in Fig. 7.5) as our contour. We only consider the singularities that are inside the contour, the others do not contribute to the integral. We proceed to compute the two residues. They are all simple so in the first case we have lim iπ / 4
z→e
( z − eiπ / 4 ) z 2 ( z − eiπ / 4 )( z − ei 3π / 4 )( z − ei 5π / 4 )( z − ei 7π / 4 )
z2 z→e ( z − ei 3π / 4 )( z − ei 5π / 4 )( z − ei 7π / 4 ) i = iπ / 4 (e − ei 3π / 4 )(eiπ / 4 − ei 5π / 4 )(eiπ / 4 − ei 7π / 4 ) 1 i = iπ / 4 iπ / 2 i 3π / 2 = − ei 3π / 4 4 2e (e − e ) = lim iπ / 4
ei3p/4
eip /4
ei5p/4
ei7p/4
Figure 7.7 An illustration of the roots in Example 7.11. For our contour, we will enclose the upper half plane, so we ignore the roots that lie in the lower half plane.
CHAPTER 7
Residue Theory
159
And so, shows that the residue corresponding to the pole at z = exp(i 3π /4) is given by z = ei 3π / 4 ⇒ − (1/ 4)eiπ / 4. Hence 1
∑ residues = − 4 e
iπ / 4
1 − ei 3π / 4 4
1 = − (cos π / 4 + i sin π / 4 + cos 3π / 4 + i sin 3π / 4) 4 i 1 1 1 =− (1 + i − 1 + i ) = − 2i = − 4 2 4 2 2 2 Therefore the integral evaluates to ⎛ i ⎞ π I = 2π i ∑ residues in upper half plane = 2π i ⎜ − = ⎝ 2 2 ⎟⎠ 2 EXAMPLE 7.12 Compute ∫ ∞−∞ [(cos x )/( x 2 − 2 x + 2)]dx. SOLUTION We can compute this integral by considering eiz eiz dz dz = ∫ z 2 − 2z + 2 ∫ [z − (1 + i)][z − (1 − i)] The root z = 1 + i lies in the upper half plane, while the root z = 1 − i lies in the lower half plane. We choose a contour which is a semicircle in the upper half plane, enclosing the first root. This is illustrated in Fig. 7.8. The residue is given by ⎧ ⎫ eiz lim ⎨[ z − (1 + i ) ] ⎬ z→i +1 [ z − (1 + i)][ z − (1 − i)] ⎭ ⎩ eiz z→i +1 z − (1 − i )
= lim =
e −1ei 2i
Complex Variables Demystified
160
y C1 1+i C2 –R
x R
0 1–i
Figure 7.8 The contour used in Example 7.12.
Therefore we have ⎛ e −1ei ⎞ π i eiz dz π = 2 i ⎜ 2i ⎟ = e e ∫ z 2 − 2z + 2 ⎝ ⎠ But, using Euler’s identity, we have ei = cos 1 + i sin 1 And so eiz dz π π ∫ z 2 − 2z + 2 = e cos(1) + i e sin(1) Now, we have eix dx eiz dz + ∫− R x 2 − 2 x + 2 C∫ z 2 − 2z + 2 1 R
=∫ =
R cos xdx sin xdx eiz dz + i + ∫− R x 2 − 2 x + 2 C∫ z 2 − 2z + 2 − R x2 − 2x + 2 1 R
π π cos(1) + i sin(1) e e
Now we let R → ∞. By Jordan’s lemma: eiz dz =0 ∫ 2 C1 z − 2 z + 2
CHAPTER 7
Residue Theory
161
So we have
∫
∞ cos xdx sin xdx π π + i∫ 2 = cos(1) + i sin(1) −∞ x − 2 x + 2 −∞ x − 2 x + 2 e e ∞
2
Equating real and imaginary parts gives the result we are looking for:
∫
∞ −∞
cos xdx π = cos(1) x − 2x + 2 e 2
Summary By computing the Laurent expansion of an analytic function in a region containing one or more singularities, we were able to arrive at the residue theorem which can be used to calculate a wide variety of integrals. This includes integrals of complex functions, but the residue theorem can also be used to calculate certain classes of integrals involving functions of a real variable.
Quiz 1. Compute ∫
γ
2. Compute ∫
γ
sinh z dz . z3 sinh z dz . z4
3. Find the principal part of f ( z ) =
1 . (1 + z 3 )2
sin z ? 5π ⎞ ⎛ z⎜z + ⎟ ⎝ 2⎠ sin z ? 5. What are the singularities and residues of 2 z (π − z ) dθ 6. Evaluate 2π ∫0 24 − 6 sinθ . 4. What are the singular points and residues of
162
Complex Variables Demystified
7. Using the technique outlined in Example 7.9, compute ∫
dx . 8. Use the residue theorem to compute lim ∫ R→∞ − R 1 + x 2 ∞ x2 + 3 9. Compute ∫−∞( x 2 + 1)( x 2 + 4) dx . −∞ cos x 10. Compute ∫ dx. −∞ 1 + x 2 R
∞ 0
sin 2 x dx . x2
CHAPTER 8
More Complex Integration and the Laplace Transform In this chapter, we consider a few more integrals that can be evaluated using the residue theorem and then consider the Laplace transform.
Contour Integration Continued Consider the Fesnel integrals which are given by
∫
∞
∞
0
0
cos(t 2 ) dt = ∫ sin(t 2 ) dt =
π 2 2
Copyright © 2008 by The McGraw-Hill Companies, Inc. Click here for terms of use.
(8.1)
Complex Variables Demystified
164
y
III
II C
p/4 I
x
Figure 8.1 The contour C used to evaluate the integrals in Eq. (8.1).
These integrals can be evaluated by considering a wedge in the first quadrant of the complex plane with angle α = π /4. This is illustrated in Fig. 8.1. The three legs along the contour have been denoted by I, II, and III. We consider the analytic function f (z) = e− z
2
(8.2)
If we integrate the function in Eq. (8.2) around C, we will find it to be zero. This can be done using the residue theorem which tells us that
∫e
− z2
C
dz = 2π i ∑ enclosed residues
This function has no singularities, a fact we can verify explicitly by writing down its series representation: e− z = 1 − z 2 + 2
1 4 1 6 z − z + 2! 3!
Therefore
∑ enclosed residues
=0
And so ∫ C e − z dz = 0. Now let’s try a different approach. First we break up the integral into separate integrals along each of the curves I, II, and III: 2
∫e
C
− z2
dz = ∫ e − z dz + ∫ e − z dz + ∫ e − z dz 2
I
2
II
2
III
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More Complex Integration
165
We take the radius of the wedge to be fixed (for now) at r = R. Now write down the polar representation: z = reiθ and dz = dr (eiθ ) + ireiθ dθ These quantities will assume different values on each leg of the contour. First consider curve I, which lies on the x axis. Along curve I, dθ = 0, θ = 0, ⇒ z = r , dz = dr. Curve II is a circular path at radius R. So while θ varies, r is fixed. So along curve II, r = R, dr = 0, ⇒ dz = iReiθ dθ . Finally, along curve III, θ is once again fixed like it was on curve I. But this time, θ = π / 4, dθ = 0, dz = eiπ / 4 dr . Using these results the integral becomes
∫e
C
− z2
R
dz = ∫ e − r dr + ∫
π /4
2
0
0
0
2 i 2θ
2 i 2θ
e − R e iReiθ dθ + ∫ e − r e eiπ / 4 dr R
Now, we let R → ∞. On curve II, as R → ∞ we have lim ∫
π /4
2 i 2θ
e − R e iReiθ dθ = 0
R→∞ 0
2 i 2θ
because e − R e → 0 is much faster than R → ∞. Earlier, we found out that ∫ C e − z dz = 0. 2 2 2 i 2θ 2 i 2θ Then we wrote ∫ C e − z dz = ∫ 0R e − r dr + ∫ π0 / 4 e − R e iReiθ dθ + ∫ 0R e − r e eiπ / 4 dr but just 2 i 2θ noted that as R → ∞ ∫ π0 / 4 e − R e iReiθ dθ = 0. So we’re left with 2
lim
{∫ e
R→∞
R
0
−r2
R
2 i 2θ
}
dr − ∫ e − r e eiπ / 4 dr = 0 0
The first integral can be looked up in a table:
∫
∞ 0
e − r dr = 2
π 2
(8.3)
Using Euler’s identity: eiπ / 4 = cos π / 4 + i sin π / 4 =
1+ i 2
Complex Variables Demystified
166 Therefore
π 1 + i ∞ − ir 2 1+ i ∞ = {cos(r 2 ) + i sin(r 2 )}ddr e dr = ∫ 2 2 0 2 ∫0 1 ∞ 1 ∞ i ∞ cos(r 2 ) dr + sin(r 2 ) dr + {cos(r 2 ) − sin(r 2 )} dr = ∫ ∫ 2 0 2 0 2 ∫0 Now equate real and imaginary parts. Clearly Im( π /2) = 0 , so it follows that i 2
∫
∞ 0
{cos(r 2 ) − sin(r 2 )} dr = 0
∞
∞
0
0
⇒ ∫ cos(r 2 ) dr = ∫ sin(r 2 ) dr Equating real parts and using ∫ ∞0 cos(r 2 ) dr = ∫ ∞0 sin(r 2 ) dr gives
π 1 = 2 2
∫
∞ 0
cos(r 2 ) dr +
∞
⇒ ∫ cos(r 2 ) dr = 0
1 2
∫
∞ 0
sin(r 2 ) dr =
2 2
∫
∞ 0
cos(r 2 ) drr
π 2 2
Next, we consider the integral ∫ 0x [dz /(1 + z 2 )], which you’ve already seen in Chap. 6. Here, we show how to do it using natural logarithms and a little trick. First we factor the integrand:
∫
x dz dz 1 x dz 1 x dz =∫ = ∫ − ∫ 2 0 1+ z 0 ( z − i )( z + i ) 2i 0 z − i 2i 0 z + i x
The last step used partial fraction decomposition. These integrals can be solved readily to give x dz 1 = − − + ln( ) ln( ) z i z i { } ∫0 1 + z 2 2i 0 x
In Fig. 8.2, we draw both lines on a triangle which will help us evaluate the integral. Notice from Fig. 8.2 that tan θ =
z =z i
⇒ θ = tan −1 z
CHAPTER 8
More Complex Integration
i
q
q –i
167
z–i
z+i
Figure 8.2 We draw triangles to evaluate ∫ 0x [dz /(1 + z 2 )] = (1 / 2i ) {ln( z − i ) − ln( z + i )} at the upper and lower limits.
Moreover we have ln( z − i ) − ln( z + i ) = ln z − i + i arg( z − i ) − {ln z + i + i arg( z + i )} = i arg( z − i ) − i arg( z + i ) = 2iθ = 2i tan −1 z Therefore the integral can be evaluated in the following way:
∫
x 0
x dz 1 = {2i tan −1 z} = tan −1 x 2 0 1+ z 2i
The Laplace Transform So far we’ve seen how complex integration can make many integrals that seem impossible to evaluate much easier to tackle. Now we turn our attention to the notion of a transform, which is a method that takes the representation of a function in terms of one variable (say time or position) and represents it in terms of a different variable like frequency. This type of mathematical operation leads to simplification of many tasks like solving differential equations, which can be turned into algebraic relationships. The first transform we will investigate is the Laplace transform. The Laplace transform is a useful mathematical tool that converts functions of time into functions of a complex variable denoted by s. This technique is very useful because the Laplace transform allows us to convert ordinary differential equations into algebraic equations which are usually easier to solve.
168
Complex Variables Demystified
A Laplace transform can be used to transform a function of time t or position x into a function of the complex variable s. In the definitions that follow, we will stick to considering functions of time, but keep in mind that x could equally well be used in place of t. We write the complex variable s in terms of real and imaginary parts as follows: s = σ + iω
(8.4)
where σ = Re(s) and ω = Im(s) are real variables. The definition of the Laplace transform is given in terms of an integral. The Laplace transform F ( s) of a function f ( t ) is given by ∞
F (s) = ∫ f (t ) e − st dt −∞
(8.5)
This can be written in an abstract form as F ( s) = L { f (t )}
(8.6)
where L {•} is the Laplace transform viewed as an operator acting on the function f ( t ). Let’s compute a few Laplace transforms using Eq. (8.5). EXAMPLE 8.1 ⎧ 1t > 0 Find the Laplace transform of f (t ) = θ (t ), where θ (t ) = ⎨ (see Fig. 8.3). ⎩0t ≤ 0 SOLUTION Inserting this function into the defining integral in Eq. (8.5) we find ∞ ∞ ∞ 1 1 F ( s) = ∫ θ (t ) e − st dt = ∫ e − st dt = − e− st = −∞ 0 0 s s
Therefore we have the Laplace transform pair
L {θ (t )} = 1s EXAMPLE 8.2 Find the Laplace transform of (see Fig. 8.4) f (t ) = e − at u(t )
CHAPTER 8
More Complex Integration
169
{q(t)} = 1s
1 0.8 0.6 0.4 0.2
–1
Figure 8.3
–0.5
0.5
1
In Example 8.1, we find the Laplace transform of f (t ) = θ (t ). This function is called the Heaviside or unit step function.
SOLUTION Again using the defining integral we have ∞
∞
∞
−∞
0
0
F (s) = ∫ e − atθ (t ) e − st dt = ∫ e − at e − st dt = ∫ e − ( a+s ) t dt 1 1 ∞ =− e − ( s+a )t | 0 = (s + a) (s + a) So we have the Laplace transform pair
L {e
− at
θ (t )} =
1 s+a
1.2 1 0.8 0.6 0.4 0.2 –3
Figure 8.4
–2
–1
1
2
3
− at In Example 8.2, we compute the Laplace transform of f (t ) = e u (t ).
Complex Variables Demystified
170 0.4
0.3
0.2
0.1
1
Figure 8.5
2
3
4
5
− at In Example 8.3 we find the Laplace transform of x (t ) = te θ (t ).
EXAMPLE 8.3 Find the Laplace transform of x (t ) = te − atθ (t ). SOLUTION The function is displayed in Fig. 8.5. Proceeding, we have ∞
∞
∞
−∞
0
0
F (s) = ∫ te − atθ (t ) e − st dt = ∫ te − at e − st dt = ∫ te − ( a+s ) t dt This is a familiar integral to most readers. No doubt many recall that this integral can be done using integration by parts. It’s always good to review so let’s quickly go through the process to refresh our memories. We start by recalling the integration by parts formula:
∫ udv = uv − ∫ vdu In the case at hand, we set u=t
⇒ du = dt
1 − ( s+a ) t e s+a Therefore, applying the integration by parts formula we obtain dv = e − ( s+a ) t dt
F (s ) = −
⇒v=−
∞ 1 ∞ − ( s+a ) t 1 te − ( s+a ) t + e dt 0 s + a ∫0 s+a
1 ∞ − ( s+a ) t e dt s + a ∫0 ∞ 1 1 =− e − ( s+a ) t = 2 0 (s + a) 2 (s + a) =
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More Complex Integration
171
So, we have derived the Laplace transform pair:
L {te
− at
θ (t )} =
1 ( s + a) 2
EXAMPLE 8.4 Let α > −1. The factorial function is defined by α ! = ∫ ∞0 e − t t α dt . Find ( −1 / 2 )! and then show that the Laplace transform of t β is given by β !/s β +1. SOLUTION Using the definition α ! = ∫ ∞0 e − t t α dt we have ∞
( −1/ 2)! = ∫ e − t t −1/ 2 dt 0
Let t = x. Then [1/(2 t )]dt = x , t = x 2 and ∞
( −1/ 2)! = ∫ e − t t −1/ 2 dt 0
∞ 2 1 ∞ 2 = 2 ∫ e − x dx = 2 ⎛⎜ ⎞⎟ ∫ e − x dx = π 0 ⎝ 2 ⎠ −∞
Using Eq. (8.5) the Laplace transform of t β is
∫
∞ 0
e − st t β dt
Let r = st. Then dr = sdt , t = r /s ⇒ β
∞ 1 − st β − r ⎛ r ⎞ dr ∫0 e t dt = ∫0 e ⎜⎝ s ⎟⎠ s = s β +1 ∞
∫
∞ 0
e − r r β dr =
β! s β +1
IMPORTANT PROPERTIES OF THE LAPLACE TRANSFORM The Laplace transform is a linear operation. This follows readily from the defining integral. Suppose that F1 ( s) = L { f1 (t )} and F2 ( s) = L { f2 (t )}. Also, let α , β be two constants. Then
L {α f (t) + β f (t )} = ∫ 1
2
∞
[α f1 (t) + β f2 ( t )] e− st dt
−∞
(8.7)
Complex Variables Demystified
172
Now, we can just use the linearity properties of the integral. We have
∫
∞
∞
[α f1 (t ) + β f2 (t )] e − st dt = ∫ [α f1 (t )e − st + β f2 (t )e − st ] dt
−∞
−∞ ∞
∞
−∞
−∞
= ∫ α f1 (t )e − st dt + ∫ β f2 (t )e − st dt ∞
∞
−∞
−∞
= α ∫ f1 (t )e − st dt + β ∫ f2 (t )e − st dt = α F1 ( s) + β F2 ( s) The next property we want to look at is time scaling. Suppose that we have a continuous function of time f (t ) and some constant a > 0. Given that ∞
F (s) = ∫ f (t ) e − st dt −∞
what is the Laplace transform of the time scaled function f (at )? The defining integral is
L { f (at )} = ∫
∞ −∞
f (at ) e − st dt
Let’s fix this up with a simple change of variables. Let u = at
⇒ du = adt
Furthermore, we can write t=
u a
So we have
L { f (at )} = ∫
∞ −∞
f (at ) e − st dt =
1 ∞ f (u ) e − su / a du a ∫−∞
Let’s write the argument of the exponential in a more suggestive way −
su s = − ⎛⎜ ⎞⎟ u = −θ u ⎝ a a⎠
where for the moment we have defined another new variable θ = s / a. This change makes the above integral look just like a plain old Laplace transform. Since the
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integration variable u is just a “dummy” variable, we can call it anything we like. Let’s put in the aforementioned changes and also let u → t
L { f (at )} = 1 ∫
∞
f (u ) e − su / a du =
1 ∞ f (u ) e −θu du a ∫−∞
a −∞ 1 ∞ 1 = ∫ f (t ) e−θt du = F (θ ) −∞ a a
Now we change back θ = s / a and we have discovered that
L { f (at )} = 1 F ⎛⎜⎝ s ⎞⎟⎠ a
a
More generally, if we let a assume negative values as well, this relation is written as
L { f (at )} =
1 ⎛ s⎞ F⎜ ⎟ a ⎝ a⎠
(8.8)
The next property we wish to consider is time shifting. Suppose that F ( s) = L { f (t )} What is the Laplace transform of x (t − t o )? Using the definition of the Laplace transform we have
L { f (t − t )} = ∫ o
∞ −∞
f (t − t o ) e− st dt
Once again, we can proceed with a simple change of variables. We let u = t − to from which it follows immediately that du = dt. Then
L { f (t − t )} = ∫ o
∞ −∞
f (u ) e − s ( u +to ) du
∞
= ∫ f (u ) e − su e − sto du −∞
Notice that s and to are not integration variables, so given any term that is a function of these variables alone, we can just pull it outside the integral. This gives
L { f (t − t )} = e ∫ − st o
o
∞ −∞
∞
f (u ) e − su du = e − sto ∫ f (t ) e − st dt = e − sto F ( s) −∞
We conclude that the effect of a time shift by to is to multiply the Laplace transform by e − sto.
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DIFFERENTIATION When we consider the derivative of a function of time, we encounter one of the most useful properties of the Laplace transform which makes it well suited to use when solving ordinary differential equations. Starting with the defining integral consider the Laplace transform
L
{ } df dt
We only consider functions that vanish when t < 0. This is just
∫
∞ 0
df − st e dt dt
Let’s use our old friend integration by parts to move the derivative away from f (t ). We obtain
∫
∞ 0
∞ ∞ df − st e dt = f (t )e − st + s ∫ f (t )e − st dt 0 0 dt
We consider the boundary term first. Clearly f (t )e − st goes to zero at the upper limit because the decaying exponential goes to zero as t → ∞. Therefore f (t )e − st
∞ = − f (0) 0
Now take a look at the integral in the second term. This is nothing other than the Laplace transform of f (t ). So, we find that
L
{ }
df = − f (0) + sF (s ) dt
(8.9)
Now let’s consider differentiation with respect to s. That is: d ∞ d [ F( s)] = ∫ f (t ) e− st dt ds −∞ ds The integration is with respect to t, so it seems fair enough that we can slide the derivative with respect to s on inside the integral. This gives ∞ ∞ d ∞ d d [ F ( s)] = ∫ [ f (t ) e − st ] dt = ∫ f (t ) ( e − st )dt = − ∫ t f (t )e − st dt −∞ −∞ ds −∞ ds ds
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We can move the minus sign to the other side, that is: −
∞ dF = ∫ t f (t )e − st dt −∞ ds
This tells us that the Laplace transform of t f (t ) is given by
L {t f (t )} = − dF
(8.10)
ds
EXAMPLE 8.5 Given that
L {cos βtu(t )} =
s s + β2 2
Find L {t cos β tu (t )} (see Fig. 8.6). SOLUTION 2 2 We obtain the result by computing the derivative of s /(s + β ) and adding a minus sign. First we recall that the derivative of a quotient is given by ⎛ f ⎞ ′ f ′ g − g′ f ⎜⎝ g ⎟⎠ = g2 6 4 2 1
2
3
4
5
6
7
–2 –4 –6
Figure 8.6
In Example 8.5, we compute the Laplace transform of t cos β tu (t ). The function is shown here with β = π .
Complex Variables Demystified
176 2 2 In the case of s /(s + β ) we have
f =s
⇒ f′ =1
g= s +β 2
2
⇒ g′ = 2s
And so ⎛ f ⎞ ′ f ′ g − g ′ f ( s 2 + β 2 ) − 2 s( s) β 2 − s2 = = = ⎜⎝ g ⎟⎠ g2 ( s 2 + β 2 )2 ( s 2 + β 2 )2 Applying Eq. (8.10) we add a minus sign and find that. EXAMPLE 8.6 Find the solution of dy = A cos t dt for t ≥ 0 where A is a constant and y ( 0 ) = 1. See Fig. 8.7. SOLUTION This is a very simple ordinary differential equation (ODE) and it can be verified by integration that the solution is y (t ) = 1 + A sin t (see Fig. 8.6). Since this is an easy ODE to solve it’s a good one to use to illustrate the method of the Laplace transform. Taking the Laplace transform of the left side, we have
L
{ }
dy = − y(0) + sY ( s) = −1 + sY ( s) dt
3 2.5 2 1.5 1 0.5 1
2
3
4
Figure 8.7 A plot of the solution to dy / dt = A cos t with A = 1 and y(0) = 1.
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In the chapter quiz, you will show that
L {cos βtu(t )} =
s s + β2 2
This tells us that the Laplace transform of the right-hand side of the differential equation is
L {A cos t} = A
s s +1 2
(remember, t ≥ 0 was specified in the problem, so we don’t need to explicitly include the unit step function). Equating both sides gives us an equation we can solve algebraically −1 + sY (s) = A
s s +1 2
Adding 1 to both sides we obtain sY (s) = 1 + A
s s +1 2
Now we divide through by s, giving an expression for the Laplace transform of y ( t ) 1 1 Y (s ) = + A 2 s s +1 Earlier we found that
L {u(t )} = 1 s
Since it has been specified that t ≥ 0, this is the same as stating that
L {1} = 1 s
In the chapter quiz, you will show that F (s ) =
β s + β2 2
178
Complex Variables Demystified
is the Laplace transform of f (t ) = sin ( β t ) u(t ). Putting these results together, by inspection of 1 1 Y (s ) = + A 2 s s +1 We conclude that y(t ) = 1 + A sin t
EXAMPLE 8.7 Abel’s integral equation is f (x) = ∫
x 0
φ (t ) dt x −t
The function f ( x ) is given while φ is an unknown. Using the Laplace transform, show that
π π F (s ) = Φ (s ) s s x
And that we can solve for the unknown using φ ( x ) = (1/ π ) ∫ [ f (t ) / x − t ] dt . 0
SOLUTION The integral of a function of time multiplied by another function of time which is shifted is called convolution. This is defined as
∫ f (t ) g ( x − t ) dt = f ∗ g
(8.11)
It can be shown that the Laplace transform turns convolution into multiplication:
L { f ∗ g} = F (s)G(s) If we take g( x ) =
1 x
(8.12)
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Then f (x) = ∫
x 0
φ (t ) dt = φ ∗ g x −t
Using the results of Example 8.3, we have
L {φ ∗ g} = Φ(s) (−1 / 2)! = Φ(s) s
π s
It follows that π / s F (s) = (π / s) Φ(s). That is, Φ(s) = s / π F (s) . Now, the Laplace transform has an inverse. Since we know that the Laplace transform of a convolution is a product and we know what the Laplace transform of a derivative is, then ⎫ s F ( s )⎬ ⎭ ⎩ π
L −1{Φ(s)} = L −1 ⎧⎨
⎫ ⎧1 π F ( s )⎬ = L −1 ⎨ s s ⎩π ⎭ =
1 −1 ⎧ π L ⎨ s F (s)⎫⎬ π ⎭ ⎩ s
=
1 d ⎡ 1 ⎤ 1 d x f (t ) = f ( x) ∗ dt ⎢ x ⎥⎦ π dx ∫0 x − t π dx ⎣
The Bromvich Inversion Integral The inverse Laplace transform is defined as follows. Consider the function g(t ) = e − ct f (t ) where c is a real constant. Now, using Fourier transforms: ∞
g(t ) = ∫ eiω t G (ω ) dω −∞
=
∫
⎛ 1 eiω t ⎜ −∞ ⎝ 2π ∞
∞
∞
−∞
0
∫
∞
⎞ e − iωτ g(τ ) dτ ⎟ dω ⎠
−∞
= ∫ eiω t ∫ e − iωτ e − cτ f (τ )dτ
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180
Using g(t ) = e − ct f (t ), we obtain the relation f (t ) =
1 2π
∫
∞
∞
e( c+iω ) t ∫ e − ( c+iω )τ f (τ ) dτ dω
−∞
0
Now let z = c + iω , then f (t ) =
1 c+i∞ z t ∞ − zτ e e f (τ ) dτ dz 2π i ∫c−i∞ ∫0
And we obtain the Bromwich inversion integral: f (t ) =
1 c+i∞ zt e F ( z ) dz 2π i ∫c−i∞
(8.13)
The Bromwich contour is a line running up and down the y axis from c − iR to c + iR (then we let R → ∞). EXAMPLE 8.8 Find the inverse Laplace transform of F (s) = 1/(s 2 + ω 2 ). SOLUTION Notice that F (s ) =
1 1 = 2 s +ω (s − iω )(s + iω ) 2
So this function has two singularities (simple poles) at s = ± iω . The inversion integral in Eq. (8.13) in this case becomes
f (t ) =
e st 1 c+i∞ ds 2π i ∫c−i∞ (s − iω )(s + iω )
The residue at s = + iω is
( s − iω )
e st eiωt = ( s − iω )( s + iω ) s = iω 2iω
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The other residue is
( s + iω )
e st e − iωt =− ( s − iω )( s + iω ) s = iω 2iω
The integral is already divided by 2π i, so by the residue theorem f (t ) = ∑ res =
eiωt e − iωt sin ω t − = 2iω 2iω ω
Summary In this chapter, we explored more complex integrals and introduced the Laplace transform, a tool which can be used to solve differential equations algebraically. The inverse Laplace transform is defined using a contour integral called the Bromvich inversion integral.
Quiz 1. Calculate the Laplace transform of cos ω t. 2. Find the Laplace transform of cosh at where a is a constant. 3. Using the Bromvich inversion integral, find the inverse Laplace transform e− k s . of s 4. Using the Bromvich inversion integral, find the inverse Laplace transform s . of 2 s +ω2 5. Using the Bromvich inversion integral and α ! = ∫ ∞0 e − t t α dt , find the inverse Laplace transform of F (s) = s −α .
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CHAPTER 9
Mapping and Transformations
In this chapter, we will introduce a few of the techniques that can be used to transform a region of the complex plane into another different region of the complex plane. You may want to do this because it will be convenient for a given problem you’re solving. There are many types of transformations that can be applied in the limited space we have, we won’t be able to cover but a small fraction of them. Our purpose here is to introduce you to a few of the common transformations used and get you used to the concepts involved. Let us define two complex planes. The first is the z plane defined by the coordinates x and y. We will now introduce a second plane, which we call the w plane, defined by two coordinates that are denoted by u and v. Mapping is a transformation between points in the z plane and points in the w plane. This is illustrated in Fig. 9.1.
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184
v
y
u
x
z plane
Figure 9.1
w plane
Mapping is a transformation of points in the z plane to points in a new w plane.
Linear Transformations A linear transformation is one that relates w to z by a linear equation of the form w = αz + β
(9.1)
where α and β are complex constants. Consider for a moment the transformation w = αz To see the effect of this transformation, we can write each factor in the polar representation. Let
α = aeiφ and as usual, denote z = reiθ . Then w = α z = (aeiφ )(reiθ ) = arei (φ +θ ) If a > 1, then the transformation expands the radius vector of z through the transformation r → ar . If a < 1, then the transformation contracts the radius vector of z as r → ar = (1/ b) r , where b > 1 . The transformation rotates the point z by an angle given by
φ = arg(α ) about the origin. The w plane is defined by the coordinate w = u + iv . EXAMPLE 9.1 Explain what the transformation w = iz does to the line y = x + 2 in the x-y plane.
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SOLUTION Note that w = iz = i ( x + iy) = − y + ix So we have the relations u = −y v=x Hence y = x + 2 ⇒ −u = v + 2 That is, the line is transformed to v = −u − 2 This linear transformation maps one line into another one, as illustrated in Fig. 9.2. EXAMPLE 9.2 Consider the transformation w = (1 + i ) z on the rectangular region shown in Fig. 9.3. SOLUTION Notice that ⎛1+ i⎞ 1+ i = 2 ⎜ = 2 (cos π /4 + i sin π /4) = 2 eiπ / 4 ⎝ 2 ⎟⎠
y
v
5 4
1 –3
3
–3
–2
–1
–2
–1
–1
2
–2
1
–3
–1 z plane
1
2
3
x
1
–4 –5 w plane
Figure 9.2 The transformation w = iz described in Example 9.1.
2
3
x
Complex Variables Demystified
186
y i
x 1
Figure 9.3 A rectangular region to be transformed by w = (1 + i) z in Example 9.2.
This tells us that the transformation will stretch lengths by 2 and rotate points in a counterclockwise direction about the origin by the angle π /4. The transformed points are w = (1 + i ) z = (1 + i )( x + iy) = x − y + i ( x + y) ⇒u= x−y v=x+y So the points on the rectangle are transformed according to (1, 0) → (1, i ) (1, i ) → (0, 2i ) (0, i ) → (−1, i ) (0, 0) → (0, 0) The transformed rectangle is illustrated in Fig. 9.4. v
p/4
u
Figure 9.4 The rectangle in Fig. 9.3 transformed by w = (1 + i) z . It is rotated by π /4 about the origin and lengths are increased by → 2 .
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If the transformation is of the form w = α z + β , the effect is to translate the region to the left or to the right by the magnitude of the real part of β , and up or down by the magnitude of the imaginary part of β . Consider the transformation w = (1 + i ) z + 3 on the rectangular region shown in Fig. 9.3. The effect of this transformation is to first rotate and expand lengths, and then to translate along the real axis. The points at the four corners of the rectangle are transformed according to (1, 0) → (4, i ) (1, i ) → (3, 2i ) (0, i ) → (2, i ) (0, 0) → (3, 0) The transformed rectangular region looks something like that in Fig. 9.5. Now let’s consider a square region in the z plane defined by 0 ≤ x ≤ 1, 0 ≤ y ≤ 1. Consider the transformation w = z +1+ i All this does is shift the square over to the right one unit and up one unit. This is illustrated in Fig. 9.6.
v
p/4 u
Figure 9.5 Adding a translation along the real axis to the transformation of Example 9.2.
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188
w=z+1+i
Figure 9.6
Consider a region that is a square by the origin. The transformation w = z + 1 + i shifts the square up and over.
The Transformation zn The transformation w = z n changes lengths according to r → r n and increases angles by a factor of n. Letting z = reiθ , we see that the transformation is given in polar coordinates as w = z n = (reiθ )n = r n einθ Before considering a mapping of a region, we let x = a be a vertical line in the plane. The transformation w = z 2 gives w = z 2 = (a + iy)2 = a 2 − y 2 + i 2ay ⇒ u = a2 − y2
v = 2ay
This allows us to set y=
v 2a
Hence the transformation is a parabola in the w plane described by the equation ⎛ v⎞ u= a −⎜ ⎟ ⎝ 2a ⎠
2
2
EXAMPLE 9.3 Consider the transformation of the quarter plane as shown in Fig. 9.7 under the mapping w = z 2 .
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y
x
Figure 9.7
In Example 9.3 we apply the transformation w = z 2 to the quarter plane defined by 0 ≤ x , 0 ≤ y .
SOLUTION We have seen that the effect of w = z n is to increase angles by a factor of n. Indeed, in this case w = z 2 = (reiθ )2 = r 2ei 2θ Hence, angles are doubled. So the angle π /2 that defines the quarter plane is expanded as π /2 → π . That is, the quarter plane is mapped to the upper half plane by this transformation. This is shown in Fig. 9.8. Generally speaking, consider a triangular region in the x-y plane with angle θ = π /n. The mapping w = z n maps this region to the half plane. This is illustrated in Fig. 9.9.
v
u
n Figure 9.8 The transformation w = z has mapped the quarter plane to the half plane.
Complex Variables Demystified
190 y
v
w = zn x
q = p/n
u
Figure 9.9 A infinite sector defined by a triangular wedge with θ = π /n is mapped to the upper half plane by the transformation w = z n if n ≥ 1/2.
Conformal Mapping Let C1 and C2 be two curves in the z plane. Suppose that a given transformation w maps these curves to curves C1′ and C2′ in the w plane. Let θ be the angle between the curves C1 and C2 and φ be the angle between curves C1′ and C2′ . If θ = φ in both magnitude and sense, we say that the mapping is conformal. Put another way, a conformal mapping preserves angles. There is an important theorem related to conformal mappings. Suppose that f ( z ) is analytic and that f ′( z ) ≠ 0 in some region R of the complex plane. It follows that the mapping w = f ( z ) is conformal at all points of R.
The Mapping 1/z Consider the transformation w = 1/z . Notice that we can write w=
1 z y x − iy x = 2 −i 2 = = 2 x + y2 z zz ( x + iy)( x − iy) x + y
By inverting the transformation, it is easy to see that the coordinates in the z plane are related to coordinates in the w plane in the same way: x=
u u + v2 2
y=−
v u + v2 2
Therefore the mapping w = 1/z • Transforms lines in the z plane to lines in the w plane • Transforms circles in the z plane to circles in the w plane
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In particular • A circle that does not pass through the origin in the z plane is transformed into a circle not passing through the origin in the w plane. • A circle passing through the origin in the z plane is transformed into a line that does not pass through the origin in the w plane. • A line not passing through the origin in the z plane is transformed into a circle through the origin in the w plane. • A line through the origin in the z plane is transformed into a line through the origin in the w plane. Let’s try to understand how w = 1/z maps lines into lines. A line in the complex plane that passes through the origin is a set of points of the form z = reia where a is some fixed angle. Under the mapping w = 1/z , we obtain a set of points: w=
1 1 − ia = e z r
This is another line that passes through the origin. An important mapping w = 1/z transforms a disk in the z plane into the exterior of the disk in the w plane. Consider the disk shown in Fig. 9.10. The mapping w = 1/z maps this to the exterior of the circle of radius 1/r . This is illustrated in Fig. 9.11. The mapping w = 1/ z takes the point z = 0 to z = ∞, and takes z = ∞ to z = 0.
y
r
x
Figure 9.10 A disk of radius r in the z plane.
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192
v
1/r
u
Figure 9.11 The transformation w = 1/z has mapped the disk in Fig. 9.9 to the entire w plane minus the region covered by the disk of radius 1/r.
Mapping of Infinite Strips There are several important transformations that can be applied to infinite strips to map them to the upper half of the w plane. Consider a strip of height a in the y direction that extends to ±∞ along the x axis. This is illustrated in Fig. 9.12. When figuring out how a transformation will work out, we pick out a few key points. These are denoted by A-F in the figure. The exponential function sends horizontal lines in the z plane into rays in the w plane. That is, consider the transformation w = ez This maps the lines as shown in Fig. 9.13.
y C
B
A a x
D
E
F
Figure 9.12 An infinite strip in the z plane.
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Mapping and Transformations
y
193
v
u
x w = ez
Figure 9.13 The exponential function maps horizontal lines to rays.
If we apply the transformation w = eπ z / a
(9.2)
to the infinite strip shown in Fig. 9.12, the result is a mapping to the upper half of the w plane, shown in Fig. 9.14. The points A, B, C, D, E, and F map to the points A′, B ′, C ′, D ′, E ′, and F ′, respectively. Now consider a vertical strip, as shown in Fig. 9.15. We can map this to the upper half plane of Fig. 9.14 using the transformation w = sin
πz a
(9.3)
v
A′
B′ –1
C′ D′
E′ 1
F′ u
Figure 9.14 A mapping w = eπ z / a to the infinite strip shown in Fig. 9.11 maps it to the upper half plane.
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y
A
a B
C
D x
Figure 9.15 To map a vertical strip to the upper half plane, we utilized the transformation w = sin π z / a. It maps to the region shown in Fig. 9.16.
Rules of Thumb Here are a few basic rules of thumb to consider when doing transformations. They can be illustrated considering the square region shown in Fig. 9.6. In that section, we saw how to shift the position of the square by adding a constant, that is, we wrote down a linear transformation of the form w = z + a. Let’s review the other types of transformations that are possible. A transformation of the type w = az will expand the region if a > 1 and will shrink the region if a < 1. Consider the first case with w = 2 z. This expands the square region from 0 ≤ x ≤ 1, 0 ≤ y ≤ 1 to 0 ≤ x ≤ 2, 0 ≤ y ≤ 2 . This is illustrated in Fig. 9.17.
v
A′
Figure 9.16
B′ –1
C′
D′ 1
E′ u
The transformation w = sin(π z / a) maps the region in Fig. 9.15 to the region in Fig. 9.16 with corresponding points indicated.
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w = 2z
Figure 9.17 For review, a transformation of the form w = az expands the region of interest if | a | >1.
Now suppose that w = (1/ 2) z. This shrinks the square, as shown in Fig. 9.18. To rotate the region by an angle φ , we use a transformation of the form w = eiφ z
(9.4)
For our square, this rotates the square by φ in the counterclockwise direction assuming that φ > 0. This is illustrated in Fig. 9.19.
Möbius Transformations In this section, we consider a transformation of the type: Tz =
az + b cz + d
ad − bc ≠ 0
w = 1/2z
Figure 9.18 We shrink the square by the transformation w = az when | a | 0. The transformation w=k
z−a z−a
(9.8)
maps the upper half of the z plane to the unit disk in the w plane. Notice that when z is purely real, | w | = | k | = 1. EXAMPLE 9.4 Consider a disk of radius r = 2 centered at the point z = −1 + i. Find a transformation that will take this to the entire complex plane with a hole of radius 1/2 centered at the origin. SOLUTION Since these transformations are linear, we can do this by taking multiple transformations in succession. First we illustrate what we’re starting with, a disk of radius r = 2 centered at the point z = −1 − i . This is shown in Fig. 9.20.
Figure 9.20
In Example 9.4, we start with a region defined by a disk centered at z = −1 + i.
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Figure 9.21 A disk at the origin is obtained from the disk shown in Fig. 9.20 via the transformation Z = z − z0 = z + 1 − i . We denote this the Z plane.
The first step is to move the disk to the origin. We do this using Z = z − z0 = z + 1 − i The result is the disk shown in Fig. 9.21. Now we want to transform the disk shown in Fig. 9.21 so that the region of definition is the entire complex plane minus a hole where the disk was. We do this using an inverse transformation: w=
1 Z
The result is shown in Fig. 9.22.
Figure 9.22 The transformation 1/Z changes the region to the entire complex plane with a hole punched out in the middle. The radius of the hole is 1/r if the radius of the disk we started with was Z = reiθ . In our example, r = 2 so the hole here has a radius ρ = 1/ 2.
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The complete transformation in this example can be written as w=
1 z +1− i
This is a Möbius transformation as in Eq. (9.5) with a = 0, b = 1, c = 1, and d = −1 + i . EXAMPLE 9.5 Construct a Möbius transformation that maps the unit disk to the left half plane Re( z ) < 0 and one that maps the unit disk to the right half plane Re( z ) > 0. SOLUTION The first transformation we want to consider is illustrated in Fig. 9.23. First we consider the boundary of the disk, which is the unit circle, that is the set of points | z | = 1. For the transformation shown in Fig. 9.23 to work, we must map the points on the unit circle to the imaginary axis. In the form of a Möbius transformation, the mapping will be of the form Tz =
az + b cz + d
This transformation has a pole located at the point z = − d /c . We are free to pick a point on the unit circle to map to the pole, so we choose z = 1. With this choice we have the freedom to fix c and d, so we choose c = 1, d = −1. So Tz =
az + b z −1
Figure 9.23 We want to map the unit disk to the left half plane.
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Second, we need to pick a point z on the unit circle such that Tz = 0. We have already used the point z = 1, so we choose z = −1. This forces us to take a = b since Tz = 0 when z = −1. We can choose a = 1 giving us the transformation Tz =
z +1 z −1
Now we can see how the transformation maps the rest of the unit disk. The simplest point to check is the point z = 0 at the center of the disk. We have Tz(0) =
0 +1 = −1 0 −1
So the transformation maps the center of the disk z = 0 to the point z = −1 which is in the left half plane. Hence this is the transformation that we want. To transform the unit disk to the right half plane instead, it turns out we are almost there. All we have to do is rotate the transformed region shown in Fig. 9.22. The angle that is required is π , and a rotation is implemented by multiplication by eiθ . So the transformation that takes the unit disk to the right half plane is given by Tz = eiπ
z +1 ⎛ z + 1⎞ = −⎜ ⎝ z − 1⎟⎠ z −1
EXAMPLE 9.6 Consider a mapping that will transform the unit disk into the upper half plane.
SOLUTION We again seek a transformation of the form Tz =
az + b cz + d
This time we choose to map the point z = −1 onto the pole at z = − d /c. If we choose c = 1, then d = 1 as well and the transformation is given by Tz =
az + b z +1
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201
Following the last example, now we need to pick a point z on the unit circle such that Tz = 0. We have already used the point z = −1, so we choose z = +1. This forces us to take a = − b since Tz = 0 when z = 1. We can choose b = 1 giving us the transformation Tz =
1− z z +1
Now we check how this transformation maps the point z = 0 at the center of the disk. We find Tz(0) =
1− 0 = +1 0 +1
This is a point in the right half plane. So the transformation does not map to the upper half plane. We can make it do so with another rotation, given by eiπ /2 = i . Hence, the transformation that will map the unit circle to the upper half plane is Tz = i
1− z z +1
Notice that it takes the point z = 0 → i , which is in the upper half plane.
Fixed Points The fixed points of a transformation are those for which Tz =
az + b =z cz + d
A fixed point is one that is left invariant by a transformation. EXAMPLE 9.7 Find the fixed points of Tz =
z −1 z+4
(9.9)
Complex Variables Demystified
202 SOLUTION The fixed points are those for which
z −1 =z z+4 ⇒ z 2 + 3z + 1 = 0 There are two fixed points: 3 5 z=− ± 2 2
Summary In this chapter, we introduced the notion of a transformation, which allows us to transform a region in the complex plane into a different region. This is a useful technique for solving differential equations, among other applications.
Quiz 1. Consider a horizontal line y = a in the z plane and let w = z2. What kind of curve results in the w plane? 2. Let x = a be a vertical line in the z plane, and let w = e z . What kind of curve results in the w plane? 3. Construct a Möbius transformation that maps the upper half of the z plane to the unit disk in the w plane with z = i → w = 0 and the point at infinity is mapped to w = −1. z +1 . 4. Find the fixed points of the transformation Tz = z −1 5. Find a Möbius transformation that maps the points z = {−1, 0,1} onto w = {− i ,1, i}. 6. Find a Möbius transformation that maps the upper half plane ( y > 0) to the half plane v > 0 and the x axis to the u axis.
CHAPTER 10
The SchwarzChristoffel Transformation
The Schwarz-Christoffel transformation is a transformation that maps a simple closed polygon to the upper half plane. The transformation can be used in applications such as fluid dynamics and electrostatics. In this chapter, we will introduce some basics about the transformation.
The Riemann Mapping Theorem The Riemann mapping theorem establishes the existence of a transformation that will map a region R of the z plane to a region R ′ of the w plane. Let w = f ( z ) be an analytic function in R and let R be enclosed by a simple closed curve C.
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204
Complex Variables Demystified
Suppose that the region R ′ is the unit disk at the origin bounded by the unit circle C ′, that is a circle with radius w = 1. The Riemann mapping theorem says that the function w = f ( z ) exists, that it maps each point of the region R into a point in R ′, and it maps each point on C to a point on C ′. Furthermore this mapping is one to one. There are three arbitrary real constants associated with the mapping w = f ( z ). To find them, we establish a correspondence between the origin of the w plane and a point belonging to R and between a point on C ′ and a point on C. If z0 ∈ R with f ( z0 ) = 0 and f ′( z0 ) > 0 then the mapping w = f ( z ) is unique.
The Schwarz-Christoffel Transformation The Schwarz-Christoffel transformation maps • The interior of a polygon to the upper half plane • The boundary of the polygon to the real axis Here we give a heuristic explanation of the transform (not a formal derivation) and state the result. Our discussion is out of Levinson and Redheffer (see the bibliography list at the end of the book). Consider the polygon shown in Fig. 10.1. In what follows, we assume the polygon is in the w plane and that it is mapped to the upper half of the z plane. As noted in the figure, the curve enclosing the region is traversed in the positive or counterclockwise sense. We define the interior angles at the vertices by
α1π , α 2π ,… , α nπ Now we assume the existence of a function w = f ( z ) that maps the interior of the polygon to the upper half plane (the existence of the function is implied by the Riemann mapping theorem). If this mapping is one-to-one and conformal (angle preserving) then it follows that f ( z ) is analytic for y > 0 and continuous for y ≥ 0.
Figure 10.1 A polygon to be mapped to the upper half plane.
CHAPTER 10
Schwarz-Christoffel
dz z
205
x
Figure 10.2 dz is a vector on the x axis of the z plane.
We can also assume the existence of an inverse mapping, which we denote by z = g( w). The inverse mapping is analytic on the polygon’s interior. Moreover, it is continuous in the interior of the polygon and on it’s boundary. The boundary of the polygon is mapped onto the real axis. Suppose that the vertices of the polygon are mapped onto the points of the real x axis denoted by x1 , x 2 ,… , x n Now, since w = f ( z ), it follows that dw = f ′( z ) dz
(10.1)
Next we assume that the mapping and its inverse w = f ( z ), z = g( w) are analytic on the sides of the polygon in addition to its interior. Picking a point w on the polygon which is not a vertex, the image of w is a point z. The point dz is a positive vector on the real axis x. This is shown in Fig. 10.2. It should follow that dw is a vector on the edge of the polygon pointing in the positive sense (in the counterclockwise direction). This is shown in Fig. 10.3. The arguments of f ′ and w ′ are then related in the following way: ⎛ dw ⎞ arg[ f ′( z )] = arg ⎜ ⎟ ⎝ dz ⎠
(10.2)
w dw
Figure 10.3 If we take dz to be a positive pointing vector on the real axis, then dw is a vector on the edge of the polygon pointing in the positive sense.
Complex Variables Demystified
206
Now imagine moving the point w around the polygon and moving the image point z in the positive direction along the x axis. Each time a point w moves past a vertex of angle α1π , the argument changes as π (1 − α1 ). But arg dz = 0. Therefore, to the left of the point x1 arg[ f ′( z )] is a constant, but at the point x1 it will change by π (1 − α1 ) to maintain Eq. (10.2). As z moves from x < x1 to x > x1, arg[( z − x1 )] decreases from π to 0. This means that the argument of ( z − x1 )α1 −1 is changed by π (1 − α1 ). This change will occur at every vertex. So we choose f ′( z ) = A( z − x1 )α1 /π −1 ( z − x 2 )α 2 /π −1 ( z − x n )α n /π −1
(10.3)
Then, using Eq. (10.1) dw = A( z − x1 )α1 /π −1 ( z − x 2 )α 2 /π −1 ( z − x n )α n /π −1 dz
(10.4)
Integrating, we obtain the form w = f ( z ): w = A ∫ ( z − x1 )α1 /π −1 ( z − x 2 )α 2 /π −1 ( z − x n )α n /π −1 dz + B
(10.5)
The constants A and B are in general complex that indicate the orientation, size, and location of the pentagon in the w plane. To obtain the mapping in Eq. (10.5), three points out of x1 , x 2 ,..., x n can be chosen. If a point x j is taken at infinity then the α / π −1 factor ( z − x j ) j is not included in Eq. (10.5). EXAMPLE 10.1 Find the image in the upper half plane using the transformation w=∫
1
z 0
(1 − t )(1 − k 2t 2 ) 2
dt
when 0 < k < 1. SOLUTION Looking at Eq. (10.5), we see that this mapping is a Schwarz-Christoffel transformation. Let’s rewrite the integral in a more suggestive form: z
w = ∫ (1 − t 2 )−1/ 2 (1 − k 2t 2 )−1/ 2 dt 0
Now the transformation looks like Eq. (10.5). To find the vertices of the polygon, we look for the zeros of the integrand. First consider 1 − t 2 = 0 , which tells us that z = ±1. Next we have 1 − k 2t 2 = 0 from which it follows that z = ±(1 / k ) . Since α j / π −1 each term in the Schwarz-Christoffel transformation is of the form ( z − x j )
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Schwarz-Christoffel
207
w = f (z)
w plane
z plane
Figure 10.4 The transformation in Example 10.1 maps a rectangle to the upper half plane.
and the exponents in this example are α j /π − 1 = −1 / 2 , it follows that α1 = α 2 = π /2 , or each angle is increased by π /2 at each vertex. The polygon described by this is a rectangle. The height of the rectangle is found from h=∫
1/ k
1
(1 − t 2 )−1/ 2 (1 − k 2t 2 )−1/ 2 dt
The width of the rectangle is 1
W = 2 ∫ (1 − t 2 )−1/ 2 (1 − k 2t 2 )−1/ 2 dt 0
Looking at the definition of the transformation, w(0) = ∫ ⎡⎣1 / (1 − t 2 )(1 − k 2 t 2 ) ⎤⎦ dt = 0, 0 so the origin of the w plane is mapped to the origin of the z plane. The vertices of the polygon are located at (−W , 0),(W , 0),(W , ih), and (−W , ih) . The transformation is illustrated in Fig. 10.4. 0
Summary In this chapter, we wrapped up the discussion of mappings or transformations begun in Chap. 9. First we stated the Riemann mapping theorem, which guarantees the existence of a mapping between a region of the w plane and a region of the z plane. Next we introduced the Schwarz-Christoffel transformation, which allows us to map a polygon to the upper half plane.
Quiz dt 1. What type of region does the transformation w = A ∫ + B map to 1− t2 the upper half plane?
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CHAPTER 11
The Gamma and Zeta Functions
In this chapter, we review two important functions related to complex analysis, the gamma and zeta functions.
The Gamma Function The gamma function can be defined in terms of complex variable z provided that Re(z) > 0 as follows: ∞
Γ( z ) = ∫ t z −1e − t dt 0
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(11.1)
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Complex Variables Demystified
We can show that Eq. (11.1) is convergent in the right-hand plane by examining its behavior at t = 0 and as t → ∞. Using | z | ≤ Re z we have t z −1e − t ≤ t Re z −1 This tells us that Eq. (11.1) is finite at t = 0. As t → ∞, note that we have t z −1e − t ≤ t Re z −1e − t ≤ e − t / 2 This shows that the integral is convergent for large t. If n is a positive integer, then Γ(n + 1) = n(n − 1)1 = n !
(11.2)
This follows from the recursion relation for the gamma function, which holds for any z (not just integers): Γ ( z + 1) = z Γ ( z )
EXAMPLE 11.1 Prove the recursion relation in Eq. (11.3) for the gamma function. SOLUTION This can be done using the definition in Eq. (11.1). We calculate Γ( z + 1): ∞
Γ( z + 1) = ∫ t z e − t dt 0
Now notice what happens if we take the derivative of the integrand: d z −t (t e ) = z t z −1e − t − t z e − t dt It follows that t z e − t = z t z −1e − t −
d z −t (t e ) dt
(11.3)
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211
So the integral can be written as ∞
Γ( z + 1) = ∫ t z e − t dt 0
∞ d = ∫ ⎡⎢ z t z −1e − t − (t z e − t ) ⎤⎥ dt 0 ⎣ dt ⎦ ∞ ∞d = ∫ z t z −1e − t dt − ∫ (t z e − t )dt 0 0 dt
Looking at the second term, we have
∫
∞ 0
d z −t (t e )dt = (t z e − t ) dt
∞ t =0
= lim t z e − t − lim t z e − t = 0 − 0 = 0 t →∞
t →0
Therefore ∞
Γ( z + 1) = ∫ t z e − t dt 0
∞
= ∫ z t z −1e − t dt 0
∞
= z ∫ t z −1e − t dt 0
⇒ Γ ( z + 1) = z Γ ( z ) EXAMPLE 11.2 Show that an alternative definition of the gamma function is given by ∞
Γ( z ) = 2 ∫ x 2 z −1e − x dx 2
0
SOLUTION This is a simple substitution problem. We start with Eq. (11.1) and choose t = x2 It follows that dt = 2 xdx
(11.4)
Complex Variables Demystified
212 Hence
∞
Γ( z ) = ∫ t z −1e − t dt 0
∞
= ∫ ( x 2 ) z −1 e − x 2 x dx 2
0
∞
= 2 ∫ x 2 z −2e − x x dx 2
0
∞
= 2 ∫ x 2 z −1e − x dx 2
0
This works provided that Re( z ) > 0. EXAMPLE111.3 n 2 Show that ∫0 x ln x dx = −1 /(1 + n) , if n > −1. SOLUTION We begin by making the substitution x = eu Then of course: dx = eu du Now the integral can be written in the following way:
∫
1 0
0
x n ln x dx = ∫ (eu )n ln(eu )eu du ∞
∞
= − ∫ (eu )n ln(eu )eu du 0
∞
= − ∫ ueu (1+n ) du 0
In the first step, we used x = eu to note that, when x = 0, ⇒ u = ∞, and when x = 1, u = 0 To see how this works note that, ln x = ln(eu ) = u,∴ x = 0 ⇒ u = ln 0 = ∞. Now
CHAPTER 11
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213
we can do another substitution. This time we let − t = u(1 + n). Then dt = − (1 + n)du . And so
∫
1 0
∞
x n ln x dx = − ∫ ueu (1+n ) du 0
∞ ⎛ − t ⎞ dt = − ∫ e− t ⎜ 0 ⎝ 1 + n ⎟⎠ − (1 + n) ∞ ⎡ t ⎤ = − ∫ e− t ⎢ dt 2 ⎥ 0 ⎣ (1 + n) ⎦ ∞ 1 =− e − t t dt 2 ∫0 (n + 1)
But, using Eq. (11.1) together with Eq. (11.2)
∫
∞ 0
e − t t dt = Γ(2) = 1! = 1
Therefore
∫
1 0
x n ln x dx = −
1 (1 + n)2
EVALUATING Γ( z ) WHEN 0 < Z < 1 It is given as a definition in most texts that ⎛ 1⎞ Γ⎜ ⎟ = π ⎝ 2⎠
(11.5)
Using the recursion formula in Eq. (11.3), it is possible to evaluate the gamma function for 0 < z < 1 if Re( z ) > 0. This result is established in the next example. EXAMPLE 11.4 Show that Γ ( z )Γ (1 − z ) = π /sin π z , and hence that Γ (1 / 2) = π . SOLUTION In Example 11.2, we showed that ∞
Γ( z ) = 2 ∫ x 2 z −1e − x dx 0
2
Complex Variables Demystified
214
It follows that (considering real z such that 0 < z < 1):
{
∞
Γ (n)Γ (1 − n) = 2 ∫ x 2 n−1e − x dx 2
0
= 4∫
∞ 0
∫
∞ 0
}{ ∫ 2
x 2 n−1 y1−2 n e − ( x
2
∞ 0
y1−2 n e − y dy
+ y2 )
2
}
dx dy
Now rewrite the integral in terms of polar coordinates x = r cosθ , y = r sin θ to give Γ (n)Γ (1 − n) = 4 ∫
π /2 0
∫
∞ 0
tan1−2 n θ re − r drdθ 2
Integration over r can be done readily yielding Γ (n)Γ (1 − n) = 2 ∫
π /2 0
tan1−2 n θ dθ
(11.6)
In order to calculate Eq. (11.6), we will have to take a major aside. We will show how to calculate the integral x p−1 ∫0 1 + x dx ∞
using residue theory. This can be done by calculating the contour integral z p−1 ∫ 1 + z dz The point z = 0 is a branch point and the point z = −1 is a simple pole. We can deal with the branch point by considering the contour shown in Fig. 11.1.
D
R
A
E –1
e
B H
G
F p−1 Figure 11.1 The contour used to evaluate ∫ [z /(1 + z)]dz has an inner circle of radius ε and an outer circle of radius R. It encloses the singularity at z = −1 while avoiding the branch point at z = 0.
CHAPTER 11
The Gamma and Zeta Functions
215
Now, recalling that −1 = eiπ we find that the residue corresponding to the singularity at z = −1 is given by lim(1 + z )
z →−1
z p−1 = lim z p−1 = ei ( p−1)π 1 + z z→eiπ
Hence by the Cauchy residue theorem z p−1 i ( p−1) π ∫ 1 + z dz = 2π ie This means that integrating around the contour we will have
∫
AB
+
∫
+
BDEFG
∫
+
GH
∫
= 2π iei ( p−1)π
HJA
On the large exterior circle we have z = R e iθ while on the small interior circle we have z = ε eiθ . That is the integral can be written as
∫
R
ε
iθ p−1 iθ p−1 2 π i p−1 ε ( xe 0 (ε e ) 2 π ( Re ) x p−1 iReiθ dθ ) dx iε eiθ dθ + + dx + ∫ ∫R 1 + xe2πi ∫2π 1 + εeiθ 0 1+ x 1 + Reiθ
= 2π iei ( p−1)π Now take the limit as ε → 0 and R → ∞ . Then
∫
BDEFG
=
∫
=0
HJA
Giving 2 π i p−1 ∞ ( xe x p−1 ) dx i ( p−1) π dx − ∫0 1 + x ∫0 1 + xe2πi = 2π ie p−1 ∞x ⇒ (1 − e 2π ( p−1) i ) ∫ dx = 2π iei ( p−1)π 0 1+ x ∞
This allows us to write x p−1 π 2π i eπ ( p−1) i 2i dx = ∫0 1 + x 1 − e2π ( p−1)i = π e pπi − e− pπi = sin pπ ∞
Complex Variables Demystified
216
After this long detour, we have calculated Eq. (11.6): Γ (n)Γ (1 − n) = 2 ∫
π /2 0
tan1−2 n θ dθ =
π sin nπ
(11.7)
Setting n = 1/ 2 it follows that 2
π ⎡ ⎛ 1⎞ ⎤ ⎢⎣ Γ ⎝ 2 ⎠ ⎥⎦ = sin(π /2) = π ⎛1 ⇒Γ ⎞ = π ⎝ 2⎠ Note that while we calculated Eq. (11.7) for real z such that 0 < z < 1, the result can be extended using analytic continuation. EXAMPLE 11.5 Using the gamma function, show that
∫
∞ 0
e − x dx . 4
SOLUTION This integral can be written as a gamma function by using a substitution. We take u = x2
⇒ du = 2 xdx
x= u
⇒ dx =
That is: du 2 u
Substituting we find
∫
∞ 0
∞
e − x dx = ∫ e − u u −1/ 2 4
2
0
du 2
1 ∞ − u2 −1/ 2 e u du 2 ∫0 1 ⎛1 = Γ ⎞ 4 ⎝ 4⎠ =
∞
To get the last step, the result of Example 11.2, Γ( z ) = 2 ∫ x 2 z −1e − x dx, was used. 0 Now noting that Γ( z ) = ( z − 1)!
2
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The Gamma and Zeta Functions
217
It follows that ⎛ 1⎞ ⎛ 1 ⎞ ⎛ 3⎞ Γ ⎜ ⎟ = ⎜ − 1⎟ ! = ⎜ − ⎟ ! ⎝ 4⎠ ⎝ 4 ⎠ ⎝ 4⎠ But we know z! z
( z − 1)! =
z! =
or
( z + 1)! z +1
This follows from the definition of factorial where n ! = n(n − 1) 1. Setting z = −3 / 4 we find that
Therefore
⎛ 3 ⎞ − +1 ! ⎛ 3 ⎞ ⎜⎝ 4 ⎟⎠ ⎛1 ⎞ = 4 ⎜ !⎟ ⎜⎝ − 4 ⎟⎠ ! = 3 ⎝4 ⎠ − +1 4
∫
∞ 0
e − x dx = 4
=
1 ⎛ 1⎞ Γ⎜ ⎟ 4 ⎝ 4⎠ 1 ⎛ 3⎞ ⎜− ⎟! 4 ⎝ 4⎠
1 ⎛1 ⎞ 4 ⎜ !⎟ 4 ⎝4 ⎠ 1 = ! 4
=
EXAMPLE 11.6 Show that Γ[(1/ 2) − n]Γ[(1/ 2) + n] = (−1)− n π . SOLUTION Recalling that Γ ( z )Γ ( z − 1) =
π sin π z
Setting z = (1/ 2) − n we obtain ⎛1 ⎞ ⎛1 ⎞ Γ ⎜ − n⎟ Γ ⎜ + n⎟ = ⎝2 ⎠ ⎝2 ⎠
π π = ⎛π ⎛1 ⎞ ⎞ sin π ⎜ − n⎟ sin ⎜ − nπ ⎟ ⎝2 ⎠ ⎝2 ⎠
Complex Variables Demystified
218
Let’s take a look at the denominator for a few values of n: ⎛π ⎛π⎞ ⎞ n = 0 : sin ⎜ − nπ ⎟ = sin ⎜ ⎟ = +1 ⎝2 ⎠ ⎝ 2⎠ ⎛π ⎛ π⎞ ⎛π ⎞ ⎞ n = 1 : sin ⎜ − nπ ⎟ = sin ⎜ − π ⎟ = sin ⎜ − ⎟ = −1 ⎝2 ⎠ ⎝2 ⎠ ⎝ 2⎠ ⎛π ⎛π ⎛ 3π ⎞ ⎞ ⎞ n = 2 : sin ⎜ − nπ ⎟ = sin ⎜ − 2π ⎟ = − sin ⎜ ⎟ = +1 ⎝2 ⎠ ⎝2 ⎠ ⎝ 2⎠ ⎛π ⎛ 5π ⎞ ⎛π ⎞ ⎞ n = 3 : sin ⎜ − nπ ⎟ = sin ⎜ − 3π ⎟ = − sin ⎜ ⎟ = −1 ⎝2 ⎝ 2⎠ ⎠ ⎝2 ⎠ We conclude that sin(π / 2 − nπ ) = (−1)n. So, we obtain ⎛1 ⎞ ⎞ ⎛1 Γ ⎜ − n⎟ Γ ⎜ + n⎟ = ⎠ ⎝2 ⎠ ⎝2
π = (−1)− n π ⎛π − nπ ⎞ sin ⎝2 ⎠
EXAMPLE 11.7 Find Γ(−1/ 2). SOLUTION To determine the value of Γ(−1/ 2), we must use the recursion relation together with analytic continuation to extend the definition into the left half of the complex plane [since Re( z ) < 0 ]. We already know that ⎛ 1⎞ Γ⎜ ⎟ = π ⎝ 2⎠ Now we use Γ ( z + 1) = z Γ ( z ) From which it follows that ⎛ 1⎞ 1 ⎛ 1⎞ Γ ⎜ − ⎟ = − Γ ⎜ ⎟ = −2 π 2 ⎝ 2⎠ ⎝ 2⎠
CHAPTER 11
The Gamma and Zeta Functions
219
More Properties of the Gamma Function In this section, we list a few properties of the gamma function that can be useful for calculation. A variation of the recursion formula shows that the gamma function is an analytic function except for simple poles which are found in the left-hand plane (see Fig. 7.2 or Figs. 11.2 and 11.3 for an illustration). The following relationship holds: Γ(z) =
Γ ( z + n + 1) z ( z + 1)( z + 2) ( z + n)
(11.8)
This tells us that the gamma function is a meromorphic function. It has simple poles located at 0, −1, −2, −3,… but is analytic everywhere else in the complex plane for Re( z ) > −(n + 1). In Example 11.8, we’ll show how to arrive at formula in Eq. (11.8). When you read the example, note how n is arbitrary, so we can expand Γ( z ) arbitrarily throughout the complex plane and it will only contain simple poles. Euler’s constant is defined to be ⎫ 1 ⎧ 1 1 γ = lim ⎨1 + + + + − ln p ⎬ = 0.5772157 p→∞ p ⎭ ⎩ 2 3
(11.9)
|Γ(z)| 6 4 2
5
5 0 Im(z)
0
0 Re(z) –5 –5
Figure 11.2 An illustration of the simple poles of the gamma function on the negative real axis.
Complex Variables Demystified
220
4
2
0
–2
–4
–4
–2
0
2
4
Figure 11.3 A contour plot of the modulus of the gamma function, in the x-y plane.
Using Euler’s constant, we can write down an infinite product representation of the gamma function: ∞ z⎞ 1 ⎛ = zeγ z ∏ ⎜ 1 + ⎟ e − z / k ⎝ k⎠ Γ( z ) k =1
(11.10)
Using Gauss’ Π function Π( z , k ): Π( z , k ) =
1 ⋅ 2 ⋅ 3 k kz ( z + 1)( z + 2) ( z + k )
(11.11)
The gamma function can be written as Γ ( z + 1) = lim Π( z , k ) k →∞
(11.12)
The duplication formula tells us that 1⎞ ⎛ 22 z −1 Γ ( z )Γ ⎜ z + ⎟ = π Γ (2 z ) ⎝ 2⎠
(11.13)
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The Gamma and Zeta Functions
221
EXAMPLE 11.8 Show that Γ(z) =
Γ ( z + n + 1) z ( z + 1)( z + 2) ( z + n)
SOLUTION Using the recursion formula: Γ ( z + 1) = z Γ ( z ) Therefore it follows that Γ ( z + 1) z We can apply the recursion formula again, letting z → z + 1, which gives Γ(z) =
Γ ( z + 2) = ( z + 1)Γ ( z + 1) Γ ( z + 2) ⇒ Γ ( z + 1) = ( z + 1) And so Γ(z) =
Γ ( z + 1) Γ ( z + 2) = z z ( z + 1)
If you carry out this procedure n times, the result follows. EXAMPLE 11.9 Show that the gamma function is analytic on the right half plane. SOLUTION Consider Γ ε (z) = ∫
1/ ε
ε
t z −1e − t dt
We can immediately show this function is analytic by computing the derivative with respect to z : dΓε d = dz dz
∫
1/ ε
ε
t z −1e − t dt = ∫
Taking the limit ε → 0 , the result follows.
1/ ε
ε
d z −1 − t (t )e dt = 0 dz
Complex Variables Demystified
222
EXAMPLE 11.10 Find the residue of the gamma function at the singularity located at z = − n, where n is an integer. SOLUTION Computing the residue of the function as written in Eq. (11.8), we have Γ ( z + n + 1) z →− n z ( z + 1)( z + 2) ( z + n) Γ ( z + n + 1) = lim z →− n z ( z + 1)( z + 2) ( z + n − 1)
lim ( z + n)Γ ( z ) = lim ( z + n)
z →− n
Γ (1) − n(− n + 1)(− n + 2) (−1) Γ (1) = (−1)n(−1)(n − 1)(−1)(n − 2) (−1) =
= (−1)n
Γ (1) (−1)n = n(n − 1)(n − 2)1 n!
The gamma function is the only meromorphic function which has the following three properties: • Γ ( z + 1) = z Γ ( z ) • Γ(1) = 1 • log Γ ( x ) is convex EXAMPLE 11.11 Show that the gamma function is logarithmically convex on the real axis. SOLUTION Saying that the gamma function is logarithmically convex on the real axis means that if we take it’s log and then find the second derivative, then let z → x , the result will be positive. This is done using the infinite product representation of Eq. (11.10). We reproduce it here for convenience: ∞ 1 z ⎛ = zeγ z ∏ 1 + ⎞ e − z / k ⎝ Γ( z ) k⎠ k =1
CHAPTER 11
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223
First, we take the logarithm of the left-hand side: log
1 = log Γ ( z )−1 = − log Γ ( z ) Γ(z)
Recalling that the log of a product is the sum of the logs, that is log AB = log A + log B, on the right-hand side we find log
∞ 1 z ⎛ = log zeγ z ∏ ⎜ 1 + ⎞⎟ e − z / k ⎝ k⎠ Γ(z) k =1
∞ z ⎧ ⎛ ⎛z ⎫ = log z + γ z + ∑ ⎨log ⎜ 1 + ⎞⎟ − ⎜ ⎞⎟ ⎬ ⎝ ⎠ ⎝ k⎠⎭ k k =1 ⎩ ∞ ∞ z ⎛ ⎛z log Γ ( z ) = − log z − γ z − ∑ log ⎜ 1 + ⎞⎟ + ∑ ⎜ ⎞⎟ ⎝ ⎠ ⎝ ⎠ k k =1 k =1 k
Therefore ⎫ ⎧ ⎛ ⎞ ⎪ ∞ 1 ⎜ −1 ⎟ ⎛ 1 ⎞ ⎪ 1 ∂ + log Γ ( z ) = − − γ + ⎨∑ ⎜ z ⎟ ⎜⎝ k ⎟⎠ ⎬ ∂z z ⎪ ⎪ k =1 k ⎜ 1 + ⎟ ⎝ k⎠ ⎭ ⎩ ∞ 1 ⎧⎛ −1 ⎞ 1 ⎫ = − − γ + ∑ ⎨⎜ ⎟⎠ + ⎬ ⎝ z k⎭ k =1 ⎩ z + k ∞ 1 ⎛1 ⎛ z ⎞ = − − γ + ∑ ⎜ ⎞⎟ ⎜ ⎝ ⎠ ⎝ z + k ⎟⎠ z k =1 k
Computing the second derivative we find ∞ ∂2 1 1 z = + log Γ ( ) ∑ 2 2 2 ∂z z k =1 ( z + k )
Evaluating this for real argument: ∞ ∂2 1 1 = + >0 log Γ ( ) x ∑ 2 2 2 ∂x x k =1 ( x + k )
when x > 0
Showing that the gamma function is logarithmically convex for real argument in the right half plane.
Complex Variables Demystified
224
Contour Integral Representation and Stirling’s Formula We close by noting that the gamma function can be written as 1 1 et = ∫ t z dt Γ( z ) 2π i
(11.14)
The contour used comes in from the negative real axis, goes counterclockwise about the origin and out along the negative real axis, avoiding the branch point at the origin. The Stirling approximation for the gamma function is given by Γ( z + 1) ≈ 2π e − z z z +1/ 2
(11.15)
The Beta Function The beta function is defined by the following integral, where Re(m) > 0 and Re(n) > 0 : 1
B(m, n) = ∫ t m−1 (1 − t )n−1 dt 0
(11.16)
By using the substitution t = sin 2 θ , we can move to polar coordinates and write the beta function in terms of trigonometric functions. First note that dt = 2sin θ cos θ dθ Using cos 2 θ + sin 2 θ = 1, we have 1
B(m, n) = ∫ t m−1 (1 − t )
n −1
0
=∫
π /2 0
= 2∫
(sin 2 θ )
π /2 0
m −1
(sin 2 θ )
dt
(cos 2 θ )n−1 2 sin θ cosθ dθ
2 m −1
(cos 2 θ )2 n−1 dθ
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225
The beta function is related to the gamma function via B( m , n ) =
Γ (m )Γ (n) Γ (m + n)
(11.17)
Furthermore, we can write B( p,1 − p) = ∫
t p−1 π dt = Γ ( p)Γ ( p − 1) = 0 1+ t sin pπ ∞
(11.18)
provided that 0 < Re( p) < 1.
The Riemann Zeta Function The Riemann zeta function was studied by Riemann for number theory. It has the following series representation:
ζ (z) =
∞ 1 1 1 1 + + + = ∑ z z z z 1 2 3 k =1 k
(11.19)
While this series is defined for Re( z ) > 0 , analytic continuation can be used to extend the zeta function to other values of z. Notice that we can write Eq. (11.19) as ∞
ζ (z) = ∑ k =1
∞ ∞ ∞ 1 1 1 = = = ∑ z ∑ ∑ e− z log k k z k =1 e log k k =1 e z log k k=1
The zeta function can be defined in terms of the gamma function via the following relationship:
ζ (z) =
1 ∞ t z −1 dt Γ ( z ) ∫0 e t + 1
(11.20)
Another way to relate the zeta and gamma functions—and to define a recursion relation for the zeta function—is by using ⎛ πz⎞ ζ (1 − z ) = 21− z π − z Γ ( z ) cos ⎜ ⎟ ζ ( z ) ⎝ 2⎠
(11.21)
When 0 < x < 1 a plot of | ζ ( z ) | shows a series of ridges located at different points along the imaginary axis. These ridges are characterized by the fact that they are monotonically decreasing. This is illustrated in Fig. 11.4. A plot over a wider range of the real axis is shown in Fig. 11.5, and a contour plot of the zeta function is shown in Fig. 11.6.
Complex Variables Demystified
226
10 8 z (x + iy) 6 4 2 0 0
100 80 60 40
0.25 0.5 x
y
20 0.75 1
Figure 11.4 A plot of the modulus of the Riemann zeta function. | ζ ( x + iy) | is characterized by monotonically decreasing ridges.
10 8 6 z (x + iy) 4 2 0 –10
10 5 0 y –5 –5
0 x
5 10
–10
Figure 11.5 A wider view of the modulus of the Riemann zeta function.
CHAPTER 11
The Gamma and Zeta Functions
227
4
2
0
–2
–4
–4
–2
0
2
4
Figure 11.6 A contour plot of the Riemann zeta function in the x-y plane.
An unproven conjecture by Riemann is that all of the zeros of ζ ( z ) can be found on the line Re( z ) = 1/ 2 . We show a plot of | ζ (1/ 2 + iy) | in Fig. 11.7, where you can see the zeros of the function for 0 ≤ y ≤ 50 . The real and imaginary parts of ζ (1/ 2 + iy) are illustrated in Figs. 11.8 and 11.9, respectively. While Riemann’s conjecture has yet to be proven, Hardy demonstrated that there are infinitely many zeros along the line Re( z ) = 1/ 2. In Fig. 11.10, we consider the Riemann zeta function for real argument. A plot of ζ ( x ) shows an asymptote at x = 1 where the function blows up. Like the gamma function, the Riemann zeta function has a representation in terms of infinite products. This is given by ⎛ 1⎞ 1⎞⎛ 1 1 ⎞⎛ 1⎞ ⎛ = ⎜1 − z ⎟ ⎜1 − z ⎟ ⎜1 − z ⎟ = ∏ ⎜1 − z ⎟ ⎝ ⎠ ⎝ ⎠ ⎝ ⎠ 5 3 2 p ⎠ ζ (z) p ⎝
(11.22)
The interesting (and maybe somewhat mysterious) feature of Eq. (11.22) is that the product is taken over all positive primes p. EXAMPLE 11.12 Is the Riemann zeta function analytic in a region of the complex plane for which Re( z ) ≥ 1 + ε where ε > 0?
Complex Variables Demystified
228 4
3.5 3
2.5 2
1.5 1
0.5 10
20
30
40
50
Figure 11.7 A plot of | ζ (1/ 2 + iy) | along the imaginary axis, showing the zeros of the zeta function.
SOLUTION To determine if the zeta function is analytic, take the series representation ∞
1 z k k =1
ζ (z) = ∑
If Re( z ) ≥ 1 + ε , then this means that x ≥ 1 + ε . And so 1 1 1 1 1 = z ln k = x ln k = x ≤ 1+ε z k e e k k 4 3 2 1 –40
–20
20
40
–1 –2
Figure 11.8 A plot of the real part of the zeta function for x = 1/ 2.
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229
2 1.5 1 0.5 –40
–20
20
40
–0.5 –1 –1.5 –2
Figure 11.9 A plot of the imaginary part of the zeta function for x = 1/ 2.
The series
∑k
1 1+ε
∞ z is convergent, so by the Weierstrass M-test ζ ( z ) = ∑ k =1 (1/ k ) is convergent as well. In fact, the zeta function converges uniformly for Re( z ) ≥ 1 + ε . This proves that if Re( z ) ≥ 1 + ε , the zeta function is analytic. The zeta function has a single simple pole located at z = 1. The residue corresponding to this singularity is one.
z{x} 4 3 2 1 –4
2
–2
4
x
–1 –2
Figure 11.10 A plot of the Riemann zeta function with real argument. Note the asymptote at x = 1 where the function blows up.
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230
Summary In this chapter, we introduced three special functions from complex analysis. These include the gamma function, the beta function, and the Riemann zeta function. These functions can be represented in different ways, using series, infinite products, or integral representations (in the case of the gamma and beta functions).
Quiz 1. Using Eqs. (11.1) and (11.2) calculate 0!. 2. Consider Gauss’ Π function. What is lim Π(3, k )? 3. Compute 4. Find
∫
4 0
∫
4 0
k →∞
y3/ 2 16 − y 2 dy using gamma or beta functions.
x 4 − x dx using gamma and beta functions.
5. Using the gamma function, calculate
∫
∞
cos(t 3 ) dt.
⎛ 1⎞ 6. Find an expression for Γ ( z )Γ (− z ) and use it to calculate Γ ⎜ − ⎟ by ⎝ 2⎠ considering Γ ( z )Γ (1 − z ). ∞ α! α 7. Considering that f ( z ) = (1 + z ) = ∑ , find an expression for n!(α − n)! n= 0 n n d f /dz z =0 in terms of gamma functions. 0
8. How can you prove that ζ (1) is divergent? Γ ( z + n) 9. Evaluate z . n Γ (n) 1 is not analytic. 10. Describe the points at which f ( z ) = ζ ( z ) − z −1
CHAPTER 12
Boundary Value Problems
Complex analysis can be utilized to solve partial differential equations. In this chapter, we consider Dirichlet problems, which involve the specification of a function that solves Laplace’s equation in a region R of the x-y plane and takes on prescribed values on the boundary of the region which a curve is enclosing R that we denote by C. A Neumann problem is one that specifies the derivative of the function on the boundary. Conformal mapping can be used to arrive at a solution to these types of problems.
Laplace’s Equation and Harmonic Functions Let’s review the concept of a harmonic function, which was introduced in Chap. 3. We say that a function φ ( x , y) is a harmonic function in a region R of the x-y plane
Copyright © 2008 by The McGraw-Hill Companies, Inc. Click here for terms of use.
Complex Variables Demystified
232 if it satisfies Laplace’s equation:
∇ 2φ =
∂ 2φ ∂ 2φ + =0 ∂x 2 ∂y 2
(12.1)
2 2 2 2 We often use the shorthand notation φ xx = ∂ φ / ∂x and φ yy = ∂ φ / ∂y to indicate partial derivatives. Recall that if a complex function f ( z ) = u( x , y) + iv ( x , y) is analytic in a region R then it follows that u( x , y) and v ( x , y) are harmonic functions. Moreover,u( x , y) and v ( x , y) are harmonic conjugates, meaning that one can be determined from the other by integration and the addition of an arbitrary constant (see Chap. 3). In polar coordinates, Eq. (12.1) becomes
∂ 2u 1 ∂u 1 ∂ 2u + =0 + ∂r 2 r ∂r r 2 ∂θ 2 The first two examples review the concept of harmonic conjugate. EXAMPLE 12.1 Find the harmonic conjugate of u( x , y) = x /( x 2 + y 2 ). SOLUTION First we compute the derivatives of the function with respect to x and y: ∂u ∂ ⎛ x ⎞ = ∂x ∂x ⎜⎝ x 2 + y 2 ⎟⎠ This derivative can be computed using the rule for quotients: ⎛ f ⎞ ′ f ′g − g ′f ⎜⎝ g ⎟⎠ = g2 Setting f = x and g = x 2 + y 2 we have f ′ = 1 and g ′ = 2 x Therefore y2 − x 2 ∂u ∂ ⎛ x ⎞ x 2 + y 2 − x (2 x ) = = = ⎜ 2 ∂x ∂x ⎝ x + y 2 ⎟⎠ ( x 2 + y 2 )2 ( x 2 + y 2 )2 A similar procedure yields the derivative with respect to y: −2 xy ∂u ∂ ⎛ x ⎞ = ⎜ 2 = 2 2⎟ ∂y ∂y ⎝ x + y ⎠ ( x + y 2 )2
(12.2)
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The Cauchy-Riemann equations tell us that ∂u ∂v = ∂x ∂y
∂v ∂u =− ∂x ∂y
Hence we have the following relationship: ∂v ∂u 2 xy = = 2 ∂x ∂y ( x + y 2 )2 x ⇒ v ( x , y) = 2 y ∫ 2 dx + F ( y) ( x + y 2 )2 2 2 If we let s = x + y ⇒ ds = 2 xdx then
v ( x , y) = y ∫
ds −y 1 + F ( y) = − y + F ( y) = 2 + F ( y) 2 s s x + y2
Now, we also have the other Cauchy-Riemann equation at our disposal, which says ∂v ∂u y2 − x 2 = = 2 ∂y ∂x ( x + y 2 )2
(12.3)
If we take the derivative with respect to y of v ( x , y) = [− y /( x 2 + y 2 )2 ] + F ( y), we obtain ∂v ∂ ⎛ − y ⎞ y2 − x 2 = ⎜ 2 + F ′ ( y) + F ( y ) = ′ ( x 2 + y 2 )2 ∂y ∂y ⎝ ( x + y 2 ) ⎟⎠ Comparison with Eq. (12.3) tells us that F ′( y) = 0, which means that F ( y) is some constant. Choosing it to be 0, we find that the harmonic conjugate to u( x , y) is v ( x , y) =
−y ( x + y 2 )2 2
EXAMPLE 12.2 Find the harmonic conjugate of u(r ,θ ) = ln r . SOLUTION To solve this problem, we recall the form of the Cauchy-Riemann equations in polar coordinates, given in Eq. (3.27): ∂u 1 ∂v = ∂r r ∂θ
1 ∂u ∂v =− r ∂θ ∂r
Complex Variables Demystified
234
Since u is a function of r only, we can immediately deduce that ∂u = 0 ⇒ v (r ,θ ) = A + f (θ ) ∂θ where A is some constant. Now 1 ∂u ∂ = ln r = r ∂r ∂r But by the Cauchy-Riemann equations, we have that ∂u / ∂r = (1/ r )(∂v / ∂θ ) . Therefore, ∂v / ∂θ = 1 which we can use to write v (r ,θ ) = ∫ dθ = θ + B where B is some constant. Comparison with v (r ,θ ) = A + f (θ ) leads us to f (θ ) = θ Ignoring the constants of integration, we conclude that the harmonic conjugate of u(r ,θ ) = ln r is v (r ,θ ) = θ
Solving Boundary Value Problems Using Conformal Mapping In this section, we apply conformal mapping techniques to the solution of boundary value problems with Dirichlet and Neumann boundary conditions. First, we state Poisson’s formulas, which give the solutions to the Dirichlet problem on the unit disk and for the upper half plane. 1. Let C be the unit circle and R its interior. Suppose that f (r ,θ ) is harmonic in R and that it assumes the value g(θ ) on the curve C, that is, f (1,θ ) = g(θ ). Then the solution to Laplace’s equation on the unit disk is given by Poisson’s formula for a circle which states that f (r ,θ ) =
1 2π
∫
2π 0
(1 − r 2 ) g(φ ) dφ 1 − 2r cos(θ − φ ) + r 2
(12.4)
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235
Next we consider a function f ( x , y) , which is harmonic in the upper half plane y > 0 and assumes the value f ( x , y) = g( x ) on the boundary, which in this case is the x axis, that is, −∞ < x < ∞ . The solution to Laplace’s equation for the upper half plane is given by f ( x , y) =
1 π
∫
y g(s ) ds −∞ y + ( x − s ) 2 ∞
2
(12.5)
We call Eq. (12.5) Poisson’s formula for the half plane. We can solve a wide variety of boundary value problems for a simply connected region R by using conformal mapping techniques. The idea is to map the region R to the unit disk or to the half plane. The mapping function that we use must be analytic. There are three steps involved in obtaining a solution: • Use a conformal transformation to map the boundary value problem for a region R to a boundary value problem on the unit disk or half plane. • Solve the problem using Eq. (12.4) or (12.5). • Find the inverse of the solution (that is apply the inverse of the conformal mapping) to write down the solution in the region R. Remember that a simply connected region is one that includes no singularities. While the mapping of the region R to a region R ′ in the w plane must be conformal, the mapping of the boundary does not have to be conformal. Three theorems are useful for solving these types of problems. The first tells us that a map w = f ( z ) has a unique inverse. The second tells us that a harmonic function is transformed into a harmonic function under an analytic mapping w = f ( z ), and finally we learn that if the boundary value of a function is constant in the z plane, then it is in the w plane as well. THEOREM 12.1 Let w = f ( z ) be analytic in a region R of the z plane. Then there exists a unique inverse z = g( w) in R if f ′( z ) ≠ 0 in R. THEOREM 12.2 Let U ( x , y) be a function in some region R of the z plane and suppose that w = f ( z ) is analytic with f ′( z ) ≠ 0. Then if φ (u, v ) is harmonic in the w plane where U ( z ) = φ ( w) are related by w = f ( z ), then U ( x , y) is harmonic. THEOREM 12.3 Let U ( x , y) = A, where A is a constant on the boundary or part of the boundary C of a region R in the z plane. Then its image φ (u, v ) = A on the boundary of the region R ′ of the w plane. If the normal derivative with respect to the boundary ∂U / ∂n = 0 in the z plane, then ∂φ / ∂n = 0 on the boundary of R ′ in the w plane as well.
Complex Variables Demystified
236
We prove theorem 12.2. We know that φ (u, v ) is harmonic in the w plane. This tells us that
φuu + φvv = 0 The coordinates u and v are functions of x and y. So we can take the derivatives of U ( x , y) using the chain rule and the fact that U ( z ) = φ ( w): U x = φu u x + φ v v x
U y = φu u y + φ v v y
⇒ U xx = φ u + 2φuv ux v x + φvv v x2 + φu uxx + φv v xx 2 uu x
U yy = φuu u y2 + 2φuv u y v y + φvv v y2 + φu u yy + φv v yy But the Cauchy-Riemann equations are also satisfied by u and v since we assumed that w = f ( z ) is analytic. So ux = v y uy = − vx Moreover, since the transformation is analytic, and f = u + iv , the coordinate functions u and v are harmonic, that is, uxx + u yy = v xx + v yy = 0. It follows that U xx + U yy = (φuu + φvv )ux2 + (φuu + φvv )u y2 + φu (uxx + u yy ) + φv ( v xx + v yy ) = 0 This concludes the proof, which showed that if φ (u, v ) is harmonic in the w plane, then U ( x , y) is harmonic in the z plane. Summarizing, the three theorems stated above tell us that given a mapping w = f ( z ) that is analytic and that takes a region R of the z plane to a region R ′ of the w plane, we have an inverse mapping z = w −1 ( z ). If φ (u, v ) solves φuu + φvv = 0 in some region R ′ of the w plane and φ ( w) = U ( z ) then it follows that U ( x , y) satisfies U xx + U yy = 0. EXAMPLE 12.3 Consider the quarter plane defined by 0 < x < ∞ , 0 < y < ∞. Solve Laplace’s equation: ∂2 f ∂2 f + =0 ∂x 2 ∂y 2 with Dirichlet boundary conditions given by f (0, y) = 1, f ( x , 0) = 0. SOLUTION We can apply conformal mapping to this problem by recalling that the map w = z n increases angles by n meaning that θ → nθ . For practice, let’s look at the quarter plane, shown in Fig. 12.1.
CHAPTER 12
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237
y
x
Figure 12.1 The problem in Example 12.3 is specified in the quarter plane 0 < x < ∞ , 0 < y < ∞.
We want a mapping that will take the angle π /2 → π , so that we can double the region and use Poisson’s formula for the half plane. Recalling our discussion in Chap. 9, the transformation or mapping that will accomplish this is: w = z2 which is given by w = ( x + iy)2 = x 2 − y 2 + i 2 xy ⇒ u = x 2 − y2
v = 2 xy
Notice that as x → ∞ for fixed y ≠ 0 that v → +∞. It also the case that as y → ∞ for fixed x ≠ 0 that v → + ∞. Since 0 < x < ∞, 0 < y < ∞, the other extreme is x = 0 or y = 0 and in either case v = 0. So, we see that we have 0 < v < ∞. On the other hand, suppose that x = 0, y → ∞ . Then u → − ∞. If y = 0, x → ∞ then u → + ∞. So we have − ∞ < u < ∞. So this map successfully generates the entire upper half plane from the quarter plane, as also explained in Chap. 9. The w plane is illustrated in Fig. 12.2. To solve the problem in the upper half plane, we use Eq. (12.5). In the w plane this is
φ (u, v ) =
1 π
∫
∞ −∞
v g(s ) ds v + (u − s)2 2
The boundary condition given is f (0, y) = 1, f ( x , 0) = 0 (in the z plane). Notice this is a Dirichlet boundary condition since the value of the function is being specified on the boundary. These boundary conditions translate into g(u, 0) = 1 for − ∞ < u < 0 and g(u, 0) = 0 for 0 < u < ∞ . This is because when x = 0, we have u = − y 2 , v = 0. Given the range of 0 < y < ∞ this fixes the boundary condition to 1 when − ∞ < u < 0 and 0 when 0 < u < ∞.
Complex Variables Demystified
238
v
u
Figure 12.2 The mapping w = z 2 transforms the quarter plane shown in Fig. 12.1 into the entire upper half plane.
Hence
φ (u, v ) =
1 π
v g(s ) 1 ∫−∞ v + (u − s)2 ds = π
=
1 π
∫
=
1 1 ⎛u − tan −1 ⎜ ⎞⎟ ⎝ v⎠ 2 π
∞
2
v g(s ) 1 ∫−∞ v + (u − s)2 ds + π 0
2
∫
∞ 0
v g(s ) ds v + (u − s)2 2
v 1 ⎛ s − u⎞ 0 1 ⎛ −u ⎞ 1 ⎛ π ⎞ − − ds = tan −1 ⎜ = tan −1 ⎟ 2 −∞ v + (u − s ) ⎝ v ⎠ π ⎝ 2⎠ ⎝ v ⎠ −∞ π π 0
2
Now 1 1 ⎛u tan −1 ⎞ = v →0 ,u =u0 > 0 π ⎝ v⎠ 2 lim
So φ (u, 0) = 0 when u > 0 as required. Secondly: 1 −1 ⎛ u ⎞ 1 tan ⎜ ⎟ = − v →0 ,u =u0 < 0 π 2 ⎝ v⎠ lim
which leads to φ (u, 0) = 1 when u < 0 . Inverting the transformation gives
φ (u, v ) = ⇒ f ( x , y) =
1 1 −1 ⎛ u ⎞ − tan ⎜ ⎟ ⎝ v⎠ 2 π 1 1 −1 ⎛ x 2 − y 2 ⎞ − tan ⎜ 2 π ⎝ 2 xy ⎟⎠
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Boundary Value Problems
239
We have ⎧1 1 ⎛ x 2 − y2 ⎞ ⎫ f (0, y) = lim f ( x , y) = lim ⎨ − tan −1 ⎜ ⎬ x →0 , y> 0 x →0 , y> 0 2 ⎝ 2 xy ⎟⎠ ⎭ π ⎩ =
⎛ x 2 − y2 ⎞ 1 1 ⎛ π ⎞ 1 1 lim tan −1 ⎜ = − ⎜− ⎟ =1 − ⎝ 2 xy ⎟⎠ 2 π ⎝ 2 ⎠ 2 π x →0 , y> 0
and ⎧1 1 ⎛ x 2 − y 2 ⎞ ⎫⎪ f ( x , 0) = lim f ( x , y) = lim ⎨ − tan −1 ⎜ ⎬ y→ 0 , x > 0 y→ 0 , x > 0 2 π ⎝ 2 xy ⎟⎠ ⎭ ⎩⎪ =
⎛ x 2 − y2 ⎞ 1 1 ⎛ π ⎞ 1 1 − lim tan −1 ⎜ = − ⎜ ⎟ =0 ⎝ 2 xy ⎟⎠ 2 π ⎝ 2 ⎠ 2 π y→ 0 , x > 0
Therefore the boundary conditions in the problem are satisfied. EXAMPLE 12.4 Consider the unit disk with boundary values specified by ⎧ 1 0 1
5. Find the Green’s function for a triangular wedge in the quarter plane with angle α (Hint: The transformation z k expands angles, choose a transformation to take α → π to cover the entire upper half plane).
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Final Exam
1. Using the definition of the derivative of a complex function in terms of limits, find f ′(z) when f (z) = z3. Δw 2. If f (z) = z find and determine if the function is differentiable. Δz 3. Find the derivative of f (z) = 3z2 − 2z. z3 f z ( ) = 4. Find the derivative of 1 + z2 . 5. Find the derivative of f (z) = (2z2 + 2i)5. 6. Is f = 2x + ixy2 analytic? 7. Is the function f = ( x + iy)3 − ( x 2 − i 2 xy − y 2 )( x + iy) analytic? 8. Find f ′(z) when f = 3 r eiθ / 2 . 9. In what domain is f = cosh x cos y + i sinh x sin y analytic? 10. Let f = u + iv be analytic. Show that v is harmonic.
Copyright © 2008 by The McGraw-Hill Companies, Inc. Click here for terms of use.
Complex Variables Demystified
250
11. Consider the gamma function. Starting with the standard definition, ⎛ 1⎞ ∞ Γ (z) = ∫ 0 t z −1e − t dt , use t = ln ⎜⎝ ⎟⎠ to reexpress the gamma function in u terms of the natural logarithm. x 2 − y2 . 12. Find the harmonic conjugate of u = 2 ( x − y 2 )2 + 4 x 2 y 2 In questions 13 to 25, use integral theorems from complex variables to evaluate the following integrals. π dx 13. ∫0 2 + sin 2 x π dx 14. ∫0 5 + 4 cos x ∞ cos x − cos a 15. ∫−∞ x 2 − a 2 dx ∞ x 3 dx 16. ∫0 ( x 3 + 2)2 ∞
17.
∫
18.
ei 2 x ∫−∞ 1 + 4 x 2 dx
sech 2 x cos x dx
−∞
∞
2π dθ 19. 1 ∫ 2 0 1 + cos 2 θ
20. 21.
∫ ∫
∞
x sin x dx ( x + 3)( x 2 + 4) 2
0 ∞ 0
x dx ( x + 3)2
22.
1 2π
23.
∫
0
24.
∫
0
25.
∫
∞
0
sin x dx −∞ x ( x 2 + 4) ∞
e − x cos 2 x dx
∞
π
∫
2
cos x dx 1+ x2 dθ 6 − 3 cos θ
Final Exam
251
Write the following in the standard form z = x + iy. 26. (1 + 2i)3 27. (1 + i)3 6i + zz 3 29. What are the real and imaginary parts of 1 + z 2 z? 28.
30. What is the modulus of 1 + z 2 z? 31. Find the modulus of z = (2 + i)2. 32. Find the modulus of z =
1 − 2i . 3
33. What is the residue of at f ( z ) = 34. What is the residue of f ( z ) = 35. Find the residue of at
1 at z = 0? z
1 at z = 0? z3
sin z z = −1. 1 + z3
36. What are the singularities of f ( z ) = 37. What is the residue of f ( z ) =
z2 ? ( z 2 + 1)( z + 4)
z2 for z = −4? ( z 2 + 1)( z + 4)
z2 when z = −2? ( z 2 + 1)( z + 2)2 z2 . 39. Find the singularities and their order of f ( z ) = z ( z + 4)( z − 2)2 Find the Laplace transform of the following: 40. e−x cos x 38. What is the residue of f ( z ) =
41. eix 42. sinh x 43. t2 e−1 If possible, use the Bromvich inversion integral to find the inverse Laplace transform of the following: s 44. 2 s +1 1 45. 2 s −1
Complex Variables Demystified
252
1 s +2 s 47. 2 s +2 1 48. 2 s + 4s − 8 s 49. 2 s(s + 1)(s − 3) 4 50. s5 Find the series expansions of the following functions about the origin. Identify the principal part if it exists: 46.
2
51. tan z 52. ez ez 53. 3 z 54. cos z 55. sin z z2 56. sinh z z cosh z 57. 3 z ln |z−2| 58. 59.
1 z +1 ln z z −1
60.
1 z ( z + 1)( z − 2)2
Calculate the following limits: z2 61. zlim →2 i 62. lim z 2 z →2
63. lim z z →1+i
Final Exam eiz 64. lim z →π cos z z →π z sin π z lim z →0 πz z lim 2 z →∞ z + 6 z lim z →0 sin z z lim z →1 ( z − 1) 2 z lim z →2 i ( z − 1) 2
65. lim 66. 67. 68. 69. 70.
Write the following as polynomials in z and z : 71. x + y2 72. x3 73. 2x − iy 74. 2x + 6iy 75. 4y2 Compute the following derivatives: 76. 77. 78. 79. 80.
∂ 2 ( x + y) ∂z ∂ 2 ( x + y) ∂z ∂ 3 (z ) ∂x ∂ 2 z ∂x ∂ | z |2 ∂x
Find the real and imaginary parts of the following functions: 81. f ( z ) = zz 82. f (z) = z2
253
Complex Variables Demystified
254
83. f (z) = ez 1 84. f ( z ) = (in polar coordinates) z 1/ 3 85. f ( z ) = z
For each of the following functions, indicate where the function may not be analytic. 1 86. f = 1 + z2 87. f = sin z z 88. f = 1 − z2 89. f = 1 − z 2 z 90. f =
2z (1 − z )( z + 2)
91. Find the harmonic conjugate function of u = y3 − 3 x 2 y . ⎛1 π⎞ 92. Evaluate exp ⎜ + i ⎟ . ⎝2 4⎠ 93. Evaluate exp(2 + 3pi). 94. Evaluate log1. 95. Calculate (1 + i)i. 96. Find ei(2n+1) where n is an integer. π⎞ ⎛ 97. Evaluate sin ⎜ z + ⎟ . ⎝ 2⎠ 98. Find sin iy. 99. Find cos iy. 100. Find the roots of the equation sin z = cosh 4.
Quiz Solutions
Chapter 1 1. 1/8 1 7 − i 5 5 3. z + w = 5 + 2i, zw = 9 + 7i
2.
4. z = 2 − 3i , w = 3 + i 5. −3π / 4
6. 3 cos 2 θ sin θ − sin 3 θ 7. sin x cosh y + i cos x sinh y 8. − i ln( z ± z 2 − 1) ⎛ 3 1⎞ ⎛ 3 1⎞ 9. ⎜ + i ⎟ ,⎜ − + i ⎟ , −i ⎝ 2 2⎠ ⎝ 2 2⎠ 10. 8eip/2
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256
Complex Variables Demystified
Chapter 2 1. 3i 2. 2 + i 3. z 2 + 2 zz − i 2 2 4. f + f = z + z + z + z + 6 2 2 5. u( x , y) = 1 + x 2 + y 2 , v ( x , y) = − y 6. 4
7. 1 8. −i 9. 0 10. No, f(1) does not exist.
Chapter 3 1. nz n−1 2. Δw = z + Δz + z Δz , no. Δz Δz 3. 24z7 − 12z 2 z 2 + 3z 4. − 6 z4 5. − i 3 x 6. ux = e cos y ≠ v y 7. ux = 1, v y = −1, so the Cauchy-Riemann equations are never satisfied, not even at the origin. So it is not differentiable. 8. Yes 9. The Cauchy-Riemann equations are satisfied, so the derivative exists everywhere in the specified domain. 10. Yes, v ( x , y) = 2 xy
Quiz Solutions
Chapter 4 1. Use the same steps applied in Example 4.5. 2. Consider e z = −1 where e x = 1, y = π (2n + 1), n = 0, ±1, ±2, . . . . 3. e2 4. 1 + tan2 z = sec2 z tan z + tan w 1 − tan z tan w 6. Yes, they must be multi-valued, because they are defined in terms of the natural log function. 5.
Chapter 5 1. N = 2
z
ε
⎛ 2. cos ⎜ nθ ⎞⎟ ⎝ 2⎠ 3. p
⎛ (n + 1)θ ⎞ sin ⎜ ⎝ 2 ⎟⎠ sin(θ / 2)
4. 4 5. Uniformly convergent to 0, |z| ≥ 2. (−1)n 4 n+1 z 2 n+ 2 n= 0 3 7. Converges absolutely ∞
6.
∑
2 n +1
8. − ∑ ( z − π i ) n = 0 (2n + 1)! ∞
9.
∞
(r /2)2 n 2 n = 0 (n !)
∑
(n + 1) n z n+ 2 n =−∞ n= 0 2 11. Removable singularity. −1
10.
∞
∑ zn + ∑
257
Complex Variables Demystified
258
Chapter 6 1. −5/4 3+i 4
2.
⎛ ⎞ 3. ⎜ 1 + i ⎟ (i + eπ / 2 ) ⎝ 2 ⎠ π 4. 1 + e 2 5. 0
6. 0 7. arctan (x) 2π 8. 5 9. −pi 8π i 10. − 2 π + 64
Chapter 7 1. 0 2. i
π 3
3. 1 1 + 2 1 9 ( z + 1)2 3 z + 1 4. Singularities: 0, −5π / 2, residues: 0, 2 / 5π 5. Singularities: 0, p, residues: 1/p, 0 6. π 7. 8. 9. 10.
3 15 p /2 p 5π 6 π e
Quiz Solutions
259
Chapter 8 1.
s s +ω2
2.
s s − a2
2
2
3. f (t ) = 4. cos wt
1
πt
e− k
2
/4 t
⎛ sin απ ⎞ α −1 t (−α )! 5. f ( x ) = ⎜ ⎝ π ⎟⎠
Chapter 9 2
v 1. A parabola described by u = ⎛⎜ ⎞⎟ − a 2 ⎝ 2a ⎠ 2. x = a is mapped to a circle |w| = ea i−z 3. w = i+z 4. z = 2 ± 2 5. w =
i−z i+z
6. Tz =
z −1 z +1
Chapter 10 1. It maps an infinitely high vertical strip with v ≥ 0 of width W = Ap + B to the upper half plane.
Complex Variables Demystified
260
Chapter 11 1. 1 2. 6 ⎤ ⎡ 3. 64 2 ⎢ Γ ⎛⎜ 1 ⎞⎟ ⎥ ⎝ ⎠ 21 π ⎣ 4 ⎦
2
4. 2p 5.
Γ
⎛ 1⎞ ⎝ 3⎠
2 3 6. Γ ( z )Γ (− z ) = −
π , Γ (−1/ 2) = −2 π z sin π z
Γ (α + 1) Γ (α − n + 1) 8. This gives the harmonic series.
7.
9. 1 10. The function is entire—it is analytic everywhere in the complex plane.
Chapter 12 1. v (r ,θ ) =
r sin θ π 1 − 2r cos θ + r 2
y 2. v ( x , y) = arctan ⎛⎜ ⎞⎟ + v0 where v0 is a constant ⎝ x⎠ ⎛ y⎞ 3. Yes, w = ln z ,U ( x , y) = arctan ⎜⎝ ⎟⎠ . x ⎛ ⎛ ⎞ ⎞ 4. A − B tan −1 ⎜ y ⎟ + B − C tan −1 ⎜ y ⎟ + C ⎝ x + 1⎠ ⎝ x − 1⎠ π π 5. G ( z , z0 ) =
z π /α − z 0 π /α 1 ln π /α 2π z − z0 π /α
CHAPTER 1
Final Exam Solutions
1. Use ( x + y)3 = x 3 + 3 x 2 y + 3 xy 2 + y3 to get f ′( z ) = 3z 2 . 2. 1, yes. 3. 6z − 2 2 4 4. 3z + z (1 + z 2 )2
5. 20z(2z2 + 2i)4 6. No 3 2 7. No, note that f ( z ) = z − z z 1 8. 3( 3 r eiθ / 2 )2
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Complex Variables Demystified
262 9. The function is entire.
10. uxy = v yy , uxy = − v xx ⇒ v xx + v yy = 0 z −1
⎡ ⎛ 1⎞ ⎤ ∫0 ⎢⎣ ln ⎜⎝ u ⎟⎠ ⎥⎦ du −2 xy 12. v = 2 ( x − y 2 )2 + 4 x 2 y 2 1
11.
13.
π
6 14. p /3 15. − π sin a a 3
16.
2π
9 3 17. 2π sinh π 18. π 2e 19. π 2 20. π (e 2− e2 21. π
3
− 1)
2 3 22. sinh(1) 4e
π 2e π 24. 2e 25. π 3 3 26. −3 + 4i 23.
27. −2 + 2i x 2 + y2 28. + 2i 3
Final Exam Solutions 29. Re = 1 + x 3 + xy 2 , Im = yx 2 + y3 (1 + x 3 + xy 2 )2 + ( yx 2 + y3 )
30. 31. 5
5 3
32. 33. 1 34. 0
35. − sin(1) 3 36. z = ± i , z = −4 37. 16/17 38. −4/25 39. z = 0, −1 order 1, z = 2 order 2 40. 41. 42. 43. 44. 45.
1+ s 1 + (1 + s)2 1 s−i 1 2 s −1 2 (1 + s)3 e− t (1 + e 2 t ) 2 sinh t
46. sin 2t 2 47. cos 2t −2 (1+ 3 ) t 48. e (e 4 3t − 1) 4 3 1 49. (e3 t − cos t − 3 sin t ) 10
50.
t4 6
51. z +
z 3 2z 5 + + 3 15
263
Complex Variables Demystified
264
52.
1 z z2 z3 1 +1+ + + + , principal part z 2 6 24 z
53.
1 1 1 1 1 1 1 z z3 + 2 + + + + + , principal part 3 + 2 + 3 z z 2z z z 2 z 3! 4! 5!
54. 1 − 55.
1 z z3 z5 1 − + − + , principal part z 3! 5! 7! z
56. 1 + 57.
z2 z4 + − 2! 4!
z2 z4 + + 3! 5!
1 1 z z3 1 1 + + + + , principal part 3 + 3 z 2 z 4! 6! 2z z
58. iπ + ln 2 − 59.
z z2 + − 2 8
iπ iπ 2z 2 2z 4 +2+ + + , principal part z 3 5 z
1 1 3z z 2 9 z 3 + − + +, principal part 4z 4 z 16 16 64 61. −4
60.
62. 4 63. 1 − i 64. −1 65. −1/p 66. 1 67. 0 68. 1 69. ∞ 70. − 2 (4 + 3i ) 25
Final Exam Solutions 2 2 71. z + z − z + zz − z 2 4 2 4 72. 1 ( z 3 + 3z 2 z + 3zz 2 + z 3 ) 8 73. z + 3z 2 74. z (1 + 3i ) + z (1 − 3i )
75. z 2 − 2 zz + z 2 1 76. x + 2i 1 77. x − 2i 2 78. 3 x + i 6 xy − 3 y 2 79. 2 x + i 2 y 80. 2x 81. u = x 2 + y 2 , v = 0 82. u = x 2 − y 2 , v = 2 xy 83. u = e x cos y, v = e x sin y cos θ sin θ 84. u = ,v = r r 1/ 3 85. u = r cos θ / 3, v = r 1/3 sin θ / 3 86. Analytic except at z = ± i 87. Analytic except at z = 0 88. Is entire 89. Not analytic, depends on z 90. Analytic except at z = 1, −2 91. v = x 3 − 3 xy 2 92.
e (1 + i ) 2
93. −e 2 94. 2nπ i n = 0, ±1, ±2,... ⎛ π ⎞ i 95. exp ⎜ − + 2nπ + ln 2⎟ ⎝ 4 ⎠ 2
265
266
Complex Variables Demystified
96. (−1)1/π 97. cos z 98. i sinh y 99. cosh y ⎛π ⎞ 100. ⎜ + 2nπ ⎟ ± 4i , n = 0, ± 1, ± 2,... ⎝2 ⎠
Bibliography
Mark J. Ablowitz and Athanassios S. Fokas, Complex Variables: Introduction and Applications, 2d ed., Cambridge University Press, Cambridge, U.K. (2003). James W. Brown and Ruel V. Churchill, Complex Variables and Applications, 7th ed., McGraw-Hill, New York (2004). Robert E. Greene and Steven G. Krantz, Function Theory of One Complex Variable, 2d ed., Graduate Studies in Mathematics Vol. 40, American Mathematical Society, Providence, Rhode Island (2002). Liang-Shin Hahn and Bernard Epstein, Classical Complex Analysis, Jones and Bartlett, Sudbury, Massachusetts (1996). Norman Levinson and Raymond M. Redheffer, Complex Variables, McGraw-Hill, New York (1970). Murray R. Spiegel, Schaum’s Outlines: Complex Variables with an Introduction to Conformal Mapping and Its Applications, McGraw-Hill, New York (1999).
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INDEX
* (asterisk), 3 { } (curly braces), 91
A Abel’s integral equation, 178 Absolute value, 12, 30 Absolutely converging series, 96 Addition: and analytic functions, 60 of arguments, 15 associative law of, 11 commutative law of, 11 of complex numbers, 2, 7 of exponents, 71, 72 identity with respect to, 11 of real/imaginary parts, 120 (See also Sum(s)) Additive inverse, 11 Alternating harmonic series, 101 Analytic function(s): Cauchy-Riemann equations for determining, 51, 53–57 continuously differentiable, 51–53, 56–57 defined, 42, 45, 59 essential singularity of, 148 harmonic, 61–63 Laurent expansion of punctured disc, 145–147 local power series expansion of, 144 necessary/sufficient conditions for, 60 properties of, 60–61, 144–148 reflection principle of, 63 and singularity, 59–60 zero result of power series expansion integration, 145 Analytic part, of series, 111, 114 Annular region, 110 Antiderivative, 127 Arc, 122
Arc cosine function, 78 Argument(s), 13 addition of, 15 of exponent, 74 Argument theorem, 138 Associative law, 11 Asterisk (*), 3
B Bessel function, 101 Beta function, 224–225 Bilinear transformation, 196 Binomial theorem, 43 “Blowing up,” function, 28, 29, 32, 33, 146 Boundary value problems, 234–245 Green’s function for Laplace equation with Dirichelet, 245 Laplace equation inside unit disk with, 239–241 Laplace equation with Dirichelet, 236–239 Laplace equation with Newmann, 241–244 theorems for solving, 235 Bounded sequence, 95 Branch, of function, 88–89 Branch cut, 88 Branch point, 88, 111 Bromwich contour, 180 Bromwich inversion integral, 179–181
C Cartesian representation, 12 Cauchy, Augustin Louis, 51 Cauchy-Goursat theorem, 127–133 Cauchy-Riemann equation(s): and analytic functions, 41–42 and continuously differentiable functions, 56–57 defined, 53–54 discovery of, 51
269 Copyright © 2008 by The McGraw-Hill Companies, Inc. Click here for terms of use.
270 Cauchy-Riemann equation(s) (Cont.): examples using, 54–56 first, 54 and harmonic functions, 61–63 polar representation of, 57–59 satisfying conditions of, 54–56 second, 54 and singularity, 59–60 Cauchy’s convergence criterion, 95 Cauchy’s inequality, 136 Cauchy’s integral formula, 135–143 and argument theorem, 138 and Cauchy’s inequality, 136 defined, 132–133 and deformation of path theorem, 137, 138 and Gauss’ mean value theorem, 137 and Liouville’s theorem, 136–137 and maximum/minimum modulus theorem, 137 and Poisson’s integral formula for circles, 138–143 and Rouche’s theorem, 138 as sampling function, 143–144 statement of, 135–136 Cauchy’s integral theorem, 131–132 Chain rule, 48 Circles: mapping, 191–192 Poisson’s formula for, 138–143, 234 Clockwise direction, 124, 125, 154 Closed contour, 122 Closure law, 11 Coefficients, 65 Commutative law, 11 Comparison test, 96 Complex analysis, 4 Complex conjugate, 2–9 forming, 2–3 of function, 24–25 rules for, 5–9 of variable, 4 Complex differentiable function, 42 Complex exponential, 14, 70–75 Complex exponents, 84–85, 88 Complex functions, 21–40 conjugate, complex (see Complex conjugate) continuity of, 38–40 defined, 21–22 derivative of, 46 domain of, 23–24 infinity, limits involving, 38 limits of, 33–38 multi-/single-valued, 33 plotting, 28–33 polar representation of, 27–28
Complex Variables Demystified real/imaginary parts of, 24–28 sequences of, 92–93 Complex integration/integrals, 117–133, 163–167 and Cauchy-Goursat theorem, 127–133 contour, 121–124 of functions, 117–119 line, 124–127 properties of, 119–121 Complex line integrals, 124–127 Complex numbers, 1–19 addition of, 2, 7 algebra of, 2–4 axioms for, 10–11 conjugate rule for, 5–9 modulus of, 3, 12 multiplication of, 7 nth roots of unity for, 16–19 and Pascal’s triangle, 9–10 polar representation of, 12–16 subtraction of, 8 variables, complex, 4–5 Complex plane, 5, 121–124 Complex polynomials, 65–70 Complex series, convergence of, 95 Conformal mapping, 190, 234 Conjugate: complex (see Complex conjugate) harmonic, 62–63, 232–234 Conjugate rule, for complex numbers, 5–9 Constant: derivative of, 45 Euler’s, 219 Continuous functions, conditions needed for, 38–40 Continuously differentiable curve, 125–126 Continuously differentiable functions: defined, 51–53, 124, 125 derivative of, 56–57 Contour integral: conversion to, 153 defined, 126–127 of gamma function, 224 Contour integration, 121–124, 163–167 Contour plot: of cosh, 82 of function, 31–33 of gamma function modulus, 220 of imaginary part, 70 of modulus, 67, 220 of real part, 69 of Riemann zeta function, 227 Convergence: disc of, 104–105 of series, 94–95, 106–108 tests of, 96–97
INDEX Convergent sequence, 92 Convergent series, 94–95, 97, 108 Convolution, 178–179 Cosecant function: derivative of, 88 hyperbolic, 84 in terms of exponentials, 76 Cosine function: derivative of, 87 hyperbolic, 79–84 series representation of, 101–104 Taylor expansion of, 100 in terms of exponentials, 75–78 Cosine inverse, 78 Cotangent function, 76, 88 Counterclockwise direction, 123 Cross ratio, 196–197 Curly braces ({ }), 91 Curve: closed, 122, 123 continuously differentiable, 125–126 direction/sense of, 123 open, 122 simple, 122, 123
D De Moivre’s theorem, 15–16 Definite integrals, evaluation of real, 151–155 Deformation of path theorem, 137, 138, 148, 149 Degree, of polynomial, 65 Deleted neighborhood, 33 Dependence, 51–53 Derivative(s): of complex exponent, 88 of complex functions, 46 of constant, 45 defined, 42 of elementary functions, 47–48, 85–88 of exponential function, 86 of hyperbolic functions, 88 and Leibniz notation, 43–45 of logarithm, 86 of natural logarithm, 87 polar representation of, 57–59 of polynomial, 45–46 product/quotient rules for, 48–50 rules for computing, 45–46 of trigonometric functions, 87–88 Difference, integral of, 119 Differentiation: of Laplace transform, 174–179 rules for, 45–46 Dilation, 196 Dirac delta function, 143–144, 244
271 Direction, of curve, 123 Dirichlet boundary conditions, 236, 237, 245 Disc: of convergence, 104–105, 109 punctured, 145–147 Disks: Laplace’s equation inside unit disk, 239–241 Laplace’s equation on, 138–139 open, 34–37 Distributive law, 11 Divergent sequence, 92 Divergent series, 94 Division: and analytic functions, 60 of complex numbers, 2, 8–9, 15, 49 Domain, of function, 22–24 Duplication formula, 220
E Elementary functions, 65–89 branches of, 88–89 complex exponentials, 70–75 complex exponents, 84–85 complex polynomials, 65–70 derivatives of, 85–88 hyperbolic, 78–84 trigonometric, 75–78 Entire function, 42, 112 Equality (of complex numbers), 4 Essential singularity, 111, 148 Euler’s constant, 219 Euler’s formula, 13–15 Expansion, of region, 194, 195 Exponential function, derivative of, 86 Exponents: additive property of, 71, 72 argument of, 74 complex, 84–85, 88
F Fesnel integrals, 163–164 Field, 11 Final examination: answers, 261–265 problems, 249–254 Fixed points, of transformation, 201–202 Fourier transform, 156, 179 Fractional transformation, 196 Function(s): complex (see Complex functions) continuous, 38–40 continuously differentiable (see Continuously differentiable functions) entire, 42, 112
272 Function(s) (Cont.): functions, 78–84 gamma (see Gamma function) harmonic (see Harmonic functions) hyperbolic, 78–84 limits of, 33–38 meromorphic, 112–114 multi-/single-valued, 33 plotting, 28–33, 66–70 Fundamental theorem: of algebra, 137 of calculus, 127–128
G Gamma function, 209–224 alternative definition of, 211–213 beta function related to, 225 contour plot of modulus of, 220 defined, 209 as logarithmically convex on real axis, 222–223 as meromorphic function, 219 properties of, 219–223 recursion relation for, 210–211 residue of, 222 Stirling approximation for, 224 when 0 < z < 1, 213–218 zeta function in terms of, 225 Gauss’ mean value theorem, 137 Gauss’ Π function, 220 Geometric series, 101 Green’s functions, 244–246 Green’s theorem, 131–132
H Harmonic conjugate, 62–63, 232–234 Harmonic functions, 42, 61–63, 231–232 Harmonic series, 101 Heaviside step function, 169 Holomorphic functions, 51, 59 Hyperbolic functions, 78–84 cosine, 79–84 derivatives of, 88 period of, 83 sin, 82–84 tan/sec/csc, 84
I Identity: with respect to addition, 11 with respect to multiplication, 11 Imaginary axis, 5 Imaginary number (i), 1
Complex Variables Demystified Imaginary part(s): addition of, 120 of complex number, 2 contour plot of, 70 of function, 24, 26 limits in terms of, 34 Infinite series, 94 Infinite strips, 192–194 Infinity: limits involving, 38 singularity at, 112 Integral(s): complex (see Complex integration/integrals) contour (see Contour integral) of difference, 119 of rational function, 155–161 Integration by parts formula, 170 Invariant, 201 Inverse: additive, 11 cosine, 78 of exponential, 74 of formulas, 14 of Laplace transform, 179–181 multiplicative, 6, 11 Inverse mapping, 205 Inverse trigonometric function, 78
J Jordan arc, 122 Jordan’s lemma, 153, 154
K Kronecker delta function, 141
L Laplace equation, inside unit disk, 239–241 Laplace transform, 167–181 defined, 167–168 and differentiation, 174–179 examples of, 168–171 inverse of, 179–181 properties of, 171–173 Laplace transform pair, 168, 169 Laplace’s equation: on disks, 138–139 and harmonic function, 231–232 with Neumann boundary conditions, 241 Laurent series, 109–111, 113, 149 Laurent series expansion, 145, 146, 148 Leibniz notation, 43–45 L’Hopital’s rule, 50
INDEX Limits: of complex functions, 33–37 of integration, 120 involving infinity, 38 of sequences, 92 Line integrals, complex, 124–127 Linear transformations, 184–188 Linearity properties, of integral, 172 Liouville’s theorem, 136–137 Logarithm: defined, 74–75 derivative of, 86 Taylor expansion of, 100
273
N Natural logarithm, 74–75, 87 Necessary condition (of analytic function), 60 Negative direction, 123–125 Neighborhood, deleted, 33 Neumann boundary conditions, 241 Neumann problem, 231 Nonterminating principal part, 148 nth root test, 96 nth roots of unity, 16–19 nth term in sequence, 91
O M Maclaurin series, 98, 102 Magnitude, 12 Mapping: 1/z, 190–192 conformal, 190, 234 illustration of, 183–184 of infinite strips, 192–194 Riemann theorem of, 203–204 of Schwarz-Christoffel transformation, 204–207 Maximum modulus theorem, 137 Meromorphic function, 112–114 Minimum modulus theorem, 137 Möbius transformations, 195–201 Modulus: of complex number, 3, 12 of complex variable, 5 contour plot of, 67, 220 of gamma function, 220 maximum/minimum modulus theorem, 137 multiplication of, 15 properties of, 12 of Riemann zeta function, 226, 227 Monotonic decreasing sequence, 95 Monotonic increasing sequence, 95 Morera’s theorem, 132 Multiple poles, 146 Multiplication: and analytic functions, 60 associative law of, 11 commutative law of, 11 of complex numbers, 2, 7, 14, 48 and convolution, 178–179 of moduli, 15 (See also Product) Multiplicative inverse, 6, 11 Multivalued functions, 33, 88, 89
ODE (ordinary differential equation), 176 1/z mapping, 190–192 Open curve, 122 Open disks, 34–37 Ordinary differential equation (ODE), 176 Orthogonality integrals, 141
P Parabola, 188 Partial fraction decomposition, 166 Partial sums, 94 Pascal’s triangle, 9–10 Period, of hyperbolic functions, 83 Plotting: of complex exponential, 70–72 of complex functions, 28–33, 66–70 Poisson kernel, 156 Poisson’s formula: for circles, 138–143, 234 for half plane, 235 Polar form, 14 Polar representation: of Cauchy-Riemann equations, 57–59 of complex functions, 27–28 of complex numbers, 12–16 Pole of order n, 111 Polygons, mapping, 205–206 Polynomials: complex, 65–70 defined, 65 derivative of, 45–46 Positive primes, 227 Positive sense, 123, 124 Power, raising to a, 15 Power series: defined, 97 Taylor/Maclaurin, 98 theorems on, 98–100
274 Power series expansion, 14, 144, 145 Primes, positive, 227 Principal branch, 75 Principal part, 154 defined, 146 nonterminating, 148 of series, 111, 113 Principal value, 13, 75 Product: and analytic functions, 60 of complex functions, 120 Product rule, 48 Punctured disc, 145–147
Q Quiz solutions, 255–260 Quotient, 60 Quotient rule, 49
R Raabe’s test, 97 Radius of convergence, 94, 97, 104–106 Ratio test, 96, 104–105 Rational function, integral of, 155–161 Rays, 192 Real axis, 5 Real part(s): addition of, 120 of complex number, 2, 7 of function, 24, 25 limits in terms of, 34 Reciprocal, of complex numbers, 15 Reciprocation, 196 Rectangular region, transformation of, 185–188 Recursion formula, 221 Recursion relation, 210 Reflection principle, 63 Removable singularity, 111, 145, 147 Residue theorem, 148–151, 164 Residues, 149–161 computing, 150–152 defined, 149 and rational function integrals, 155–161 and real definite integrals, 151–155 Riemann, George Friedrich Bernhard, 51 Riemann mapping theorem, 203–204 Riemann zeta function, 225–229 as analytic function, 227–229 contour plot of modulus of, 227 modulus of, 226 Root (of number), 16–19 Root test, 106
Complex Variables Demystified Rotation, of region, 195, 196 Rouche’s theorem, 138
S Sampling function, 143–144 Schwarz-Christoffel transformation, 203–207 applications of, 203 defined, 203 mapping, 204–207 Secant function: derivative of, 88 hyperbolic, 84 in terms of exponentials, 76 Sense, of curve, 123 Sequences, 91–93 bounded, 95 of complex functions, 92–93 limits of, 92 monotonic increasing/decreasing, 95 Series: alternating harmonic, 101 of Bessel function, 101 common, 100–109 convergence of, 94–97, 106–109 of cosine function, 101–104 disc of convergence for, 104–105 geometric, 101 harmonic, 101 of hyperbolic sine, 102–103 infinite, 94 Laurent, 109–111 power, 97–100 radius of convergence for, 106 and singularity, 111–112 Taylor/Maclaurin, 98 Shrinkage, of region, 194, 195 Simple closed curve, 122, 123 Simple curve, 122, 123 Simply connected region, 235 Sin function: derivative of, 87 hyperbolic, 82–84 series representation of, 102–103 Taylor expansion of, 100 in terms of exponentials, 75–78 Single-valued functions, 33 Singular point of z, 59–60, 111, 114 Singularity, 111 defined, 59–60 essential, 111, 148 of function, 146–147, 150 at infinity, 112
INDEX nature of, 147 at origin, 28 removable, 111, 145, 147 Square region, transformation of, 187–188 Standard Cartesian notation, 25 Stirling approximation, 224 Subtraction: and analytic functions, 60 of complex numbers, 2, 8 Sufficiency condition (of analytic function), 60 Sum(s): and analytic functions, 60 integral of, 119 partial, 94
T Tangent function: derivative of, 88 hyperbolic, 84 Taylor expansion of, 100 in terms of exponentials, 75 Taylor series expansion, 13, 98, 100 Time scaling, 172–173 Time shifting, 173 Transform: defined, 167 Laplace (see Laplace transform) Transformation(s): fixed points of, 201–202 linear, 184–188 Möbius, 195–201
275 rules of thumb for, 194–195 Schwarz-Christoffel, 203–207 zn, 188–190 (See also Mapping) Translation, 196 Triangle inequality, 12 Triangular region, transformation of, 189–190 Trigonometric functions, 75–78, 87–88 (See also specific trigonometric functions, e.g., Cosine function)
U Uniformly convergent series, 97, 108 Unit step function, 169
V Value, of function, 22
W Weierstrass M-test, 97, 99–100, 107
X x axis, approaching origin along, 37
Y y axis, approaching origin along, 37
Z z plane, 5 Zeta function, Riemann (see Riemann zeta function) zn transformation, 188–190